U.S. patent application number 14/447871 was filed with the patent office on 2014-11-20 for lens barrel.
The applicant listed for this patent is Panasonic Corporation. Invention is credited to Akio KONISHI, Takumi KUWAHARA, Fumio SHINANO, Tetsuya UNO.
Application Number | 20140340751 14/447871 |
Document ID | / |
Family ID | 48904945 |
Filed Date | 2014-11-20 |
United States Patent
Application |
20140340751 |
Kind Code |
A1 |
KONISHI; Akio ; et
al. |
November 20, 2014 |
LENS BARREL
Abstract
The lens barrel includes a first frame body, a second frame
body, a support frame, and a retracting lens frame. The second
frame body is supported by the first frame body. The support frame
is supported by the second frame body and move with respect to the
second frame body within a plane. The plane being perpendicular to
the optical axis. The retracting lens frame is supported by the
support frame and move around a retraction shaft during a
transition period between an imaging enabled state and a housed
state. The retraction shaft is substantially parallel to the
optical axis. The second frame body, the support frame, and the
retracting lens frame move in the optical axis direction with
respect to the first frame body during the transition period. The
first frame body restricts the movement of the support frame within
the plane during the transition period.
Inventors: |
KONISHI; Akio; (Hyogo,
JP) ; KUWAHARA; Takumi; (Nara, JP) ; UNO;
Tetsuya; (Osaka, JP) ; SHINANO; Fumio; (Osaka,
JP) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Panasonic Corporation |
Osaka |
|
JP |
|
|
Family ID: |
48904945 |
Appl. No.: |
14/447871 |
Filed: |
July 31, 2014 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
PCT/JP2013/000588 |
Feb 1, 2013 |
|
|
|
14447871 |
|
|
|
|
Current U.S.
Class: |
359/557 |
Current CPC
Class: |
G03B 5/00 20130101; G02B
27/646 20130101; G03B 3/10 20130101; G03B 2205/0015 20130101; G02B
7/102 20130101; G02B 7/04 20130101; G03B 17/04 20130101; G03B
2205/00 20130101 |
Class at
Publication: |
359/557 |
International
Class: |
G02B 27/64 20060101
G02B027/64; G02B 7/04 20060101 G02B007/04 |
Foreign Application Data
Date |
Code |
Application Number |
Feb 2, 2012 |
JP |
2012-021380 |
Feb 2, 2012 |
JP |
2012-021395 |
Claims
1. A lens barrel, comprising: a first frame body; a second frame
body configured to be supported by the first frame body; a support
frame configured to be supported by the second frame body and move
with respect to the second frame body within a plane, the plane
being perpendicular to the optical axis; and a refracting lens
frame configured to be supported by the support frame and move
around a refraction shaft during a transition period between an
imaging enabled state and a housed state, the refraction shaft
being substantially parallel to the optical axis, the second frame
body, the support frame, and the retracting lens frame is
configured to move in the optical axis direction with respect to
the first frame body during the transition period between the
imaging enabled state and the housed state, and the first frame
body is configured to restrict the movement of the support frame
within the plane during the transition period between the imaging
enabled state and the housed state.
2. The lens barrel according to claim 1, wherein the first frame
body includes a restrictor, the restrictor configured to restrict
the movement of the support frame during the transition period
between the imaging enabled state and the housed state, and the
support frame includes an engagement portion, the engagement
portion configured to engage with the restrictor.
3. The lens barrel according to claim 1, wherein the restrictor is
a first protrusion, the first protrusion provided to the first
frame body and configured to protrude in the optical axis
direction, and the engagement portion is a second protrusion, the
second protrusion configured to protrude from the outer peripheral
part of the support frame, the second protrusion comes into contact
with the first protrusion.
4. The lens barrel according to claim 1, wherein the restrictor is
a groove, the groove being provided to the first frame body, and
the engagement portion is a third protrusion, the third protrusion
configured to protrude from the outer peripheral part of the
support frame and come into contact with the groove.
5. A lens barrel having a lens system, comprising: a support frame
configured to support a refracting lens frame, the refracting lens
frame including a retracting lens; a second frame including an
actuator, the actuator configured to move the support frame within
a plane, the plane being perpendicular to the optical axis of the
lens system; and a first frame disposed in the direction in which
the second frame moves in the optical axis direction, the first
frame body includes a restricting mechanism and a refracting
mechanism, the restricting mechanism configured to restrict a
position of the support frame, the refracting mechanism configured
to retract the retracting lens of the retracting lens frame, and
the first frame body retracts the refracting lens of the refracting
lens frame with the refracting mechanism after restricting the
position of the support frame with the restricting mechanism, when
the second frame approaches the first frame.
6. The lens barrel according to claim 5, wherein the restricting
mechanism restricts the position of the support frame in the
opposite direction with respect to a force generating on the
support frame, when the retracting mechanism refracts the
refracting lens of the refracting lens frame.
7. The lens barrel according to claim 5, wherein the restricting
mechanism restricts the position of the support frame in the same
direction with respect to a force generating on the support frame,
when the refracting mechanism retracts the refracting lens of the
refracting lens frame.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This is a continuation application of International
Application PCT/JP2013/000588, with an international filing date of
Feb. 1, 2013 which claims priority to Japanese Patent Application
No. 2012-021380 filed on Feb. 2, 2012 and Japanese Patent
Application No. 2012-021395 filed on Feb. 2, 2012. The entire
disclosures of International Application PCT/JP2013/000588,
Japanese Patent Application No. 2012-021380, and Japanese Patent
Application No. 2012-021395 are hereby incorporated herein by
reference.
BACKGROUND
[0002] 1. Technical Field
[0003] The technology disclosed herein relates to a lens barrel
equipped with an optical system.
[0004] 2. Background Information
[0005] A lens barrel in which a blur correction lens group chamber
was able to retract to the outside of a fourth lens group chamber
in a direction perpendicular to the optical axis has been disclosed
in the past (see Japanese Laid-Open Patent Application
2007-163961).
[0006] With prior art, in the imaging state, a blur correcting lens
group chamber (corresponds to the retracting lens frame) is shifted
and displaced by a blur correction mechanism of a third lens group
chamber in a direction perpendicular to the optical axis. This
reduces image blur. In the housed state, this blur correcting lens
group chamber is retracted outward in the radial direction of
fourth lens group chamber. In this state, clearance must be
provided between the fourth lens group chamber and the blur
correcting lens group chamber so that the blur correcting lens
group chamber does not touch the fourth lens group chamber. This
clearance hindered attempts to make the lens barrel more
compact.
[0007] The technology disclosed herein was conceived in light of
the above problem, and it is an object of the present technology to
reduce the size of a lens barrel.
SUMMARY
[0008] The lens barrel disclosed herein comprises a first frame
body, a second frame body, a support frame, and a retracting lens
frame. The second frame body is configured to be supported by the
first frame body. The support frame is configured to be supported
by the second frame body and move with respect to the second frame
body within a plane. The plane being perpendicular to the optical
axis. The refracting lens frame is configured to be supported by
the support frame and move around a refraction shaft during a
transition period between an imaging enabled state and a housed
state. The retraction shaft is substantially parallel to the
optical axis. The second frame body, the support frame, and the
refracting lens frame is configured to move in the optical axis
direction with respect to the first frame body during the
transition period between the imaging enabled state and the housed
state. The first frame body is configured to restrict the movement
of the support frame within the plane during the transition period
between the imaging enabled state and the housed state.
[0009] The technology disclosed herein provides a lens barrel that
can be made more compact.
BRIEF DESCRIPTION OF THE DRAWINGS
[0010] Referring now to the attached drawings, which form a part of
this original disclosure:
[0011] FIG. 1 is an oblique view of a digital camera pertaining to
Embodiment 1;
[0012] FIG. 2 is an oblique view of a lens barrel in its retracted
state;
[0013] FIG. 3 is an oblique view of the lens barrel in its wide
angle state;
[0014] FIG. 4 is an exploded oblique view of the lens barrel;
[0015] FIG. 5 is an oblique view of a master flange and a shutter
unit;
[0016] FIG. 6 is a cross section of the master flange and the
shutter unit;
[0017] FIG. 7 is a detail side view of a refraction cam of the
master flange;
[0018] FIG. 8 is an oblique view of the shutter unit, an OIS frame,
and a retracting lens frame;
[0019] FIG. 9 is a detail oblique view of the shutter unit;
[0020] FIG. 10 is a diagram in which the OIS frame to which the
retracting lens frame has been mounted is viewed from the imaging
element side;
[0021] FIG. 11 is a cross section of the area near a shaft
support;
[0022] FIG. 12 is a cross section of the area near an anti-rotation
portion;
[0023] FIG. 13 is a diagram of a rail portion of the OIS frame, and
the movement range of a third lens group;
[0024] FIG. 14 is an oblique view of the OIS frame to which the
retracting lens frame is mounted;
[0025] FIG. 15A is a diagram of the OIS frame to which the
retracting lens frame is mounted, as viewed from the imaging
element side (imaging enabled state);
[0026] FIG. 15B is a diagram of the OIS frame to which the
refracting lens frame is mounted, as viewed from the imaging
element side (refracted state);
[0027] FIG. 16 is a side view of the refracting lens frame;
[0028] FIG. 17A is a cross section of the support shaft along a
plane that is perpendicular to the axis;
[0029] FIG. 17B is a diagram of the correspondence between the
refracting lens frame and a rotary spring (part 1);
[0030] FIG. 17C is a diagram of the correspondence between the
refracting lens frame and a rotary spring (part 2);
[0031] FIG. 18 is a cross section of the positional relation
between a third lens group and a contact portion;
[0032] FIG. 19 is a diagram of the layout of an actuator and the
retracting lens frame;
[0033] FIG. 20 is a simplified cross section of the lens group in
its refracted state;
[0034] FIG. 21 is a simplified cross section of the lens group in
its wide angle state;
[0035] FIG. 22 is a simplified cross section of the lens group in
its telephoto state;
[0036] FIG. 23 is an oblique view of the lens barrel pertaining to
Embodiment 2;
[0037] FIG. 24 is an exploded oblique view of the lens barrel;
[0038] FIG. 25 is a simplified cross section of the lens group in
its refracted state;
[0039] FIG. 26 is a simplified cross section of the lens group in
its wide angle state;
[0040] FIG. 27 is a simplified cross section of the lens group in
its telephoto state;
[0041] FIG. 28 is an oblique view of a third rectilinear frame;
[0042] FIG. 29 is an oblique view of the third rectilinear
frame;
[0043] FIG. 30 is an oblique view of a shutter frame;
[0044] FIG. 31 is an oblique view of the shutter frame, the OIS
frame, and the retracting lens frame;
[0045] FIG. 32 is an oblique view of the OIS frame;
[0046] FIG. 33 is a detail cross section of the state when the
retracting lens frame has been engaged with the anti-rotation
portion of the OIS frame in another embodiment;
[0047] FIG. 34 is an oblique view of a digital camera pertaining to
Embodiment 3;
[0048] FIG. 35 is an oblique view of the lens barrel;
[0049] FIG. 36 is an exploded oblique view of the lens barrel;
[0050] FIG. 37 is an oblique view of a stationary frame;
[0051] FIG. 38 is an oblique view of a first rectilinear frame;
[0052] FIG. 39 is an oblique view of a first rotary frame;
[0053] FIG. 40 is an oblique view of a second rectilinear
frame;
[0054] FIG. 41 is an oblique view of a second rotary frame;
[0055] FIG. 42A is an oblique view of the third rectilinear
frame;
[0056] FIG. 42B is an oblique view of the third rectilinear
frame;
[0057] FIG. 43 is a simplified diagram of when the second
rectilinear frame, the second rotary frame, and the third
rectilinear frame have been assembled;
[0058] FIG. 44 is an oblique view of a first lens group frame;
[0059] FIG. 45A is an oblique view of a second lens group
frame;
[0060] FIG. 45B is a diagram of a second lens group frame as viewed
from the front;
[0061] FIG. 45C is an oblique view of the relation between the
second lens group frame and a sheet member;
[0062] FIG. 46A is an oblique view of a shutter frame;
[0063] FIG. 46B is a diagram of the shutter frame as viewed from
the subject side;
[0064] FIG. 47A is an oblique view of the shutter frame, the OIS
frame, and the retracting lens frame;
[0065] FIG. 47B is a cross section of the shutter frame, the OIS
frame, the retracting lens frame, and the second lens group
frame;
[0066] FIG. 48A is an oblique view of the OIS frame;
[0067] FIG. 48B is a detail cross section of the state when the
retracting lens frame has been engaged with the anti-rotation
portion of the OIS frame;
[0068] FIG. 49A is a cross section of the state when a rotary
spring biases the refracting lens frame to the OIS frame;
[0069] FIG. 49B is a detail cross section of the contact state
between a retraction shaft and a contact face;
[0070] FIG. 50A is an oblique view of the relation between the
second lens group frame and the refracting lens frame (imaging
enabled state);
[0071] FIG. 50B is an oblique view of the relation between the
second lens group frame and the refracting lens frame (refracted
state);
[0072] FIG. 51A is a diagram of the relation between the shutter
frame and the refracting lens frame (imaging enabled state);
[0073] FIG. 51B is a cross section of the relation between the
shutter frame and the refracting lens frame (imaging enabled
state);
[0074] FIG. 51C is a diagram of the relation between the shutter
frame and the retracting lens frame (refracted state);
[0075] FIG. 52 is a diagram of the retracting lens frame as viewed
from the imaging element side;
[0076] FIG. 53 is a simplified cross section of the lens barrel in
its refracted state;
[0077] FIG. 54 is a simplified cross section of the lens barrel in
its wide angle state;
[0078] FIG. 55 is a simplified cross section of the lens barrel in
its telephoto state;
[0079] FIG. 56A is a side view of the rotary spring pertaining to
another embodiment;
[0080] FIG. 56B is a side view of the state when the rotary spring
pertaining to another embodiment has been mounted to the retracting
lens frame; and
[0081] FIG. 57 is a detail cross section of the state when the
retracting lens frame is engaged with the anti-rotation portion of
the OIS frame in another embodiment.
DETAILED DESCRIPTION OF EMBODIMENTS
[0082] Selected embodiments of the present technology will now be
explained with reference to the drawings. It will be apparent to
those skilled in the art from this disclosure that the following
descriptions of the embodiments of the present technology are
provided for illustration only and not for the purpose of limiting
the technology as defined by the appended claims and their
equivalents.
[0083] Embodiments will now be described through reference to the
drawings.
First Embodiment
[0084] A first embodiment will be described through reference to
FIGS. 1 to 22. The numbers and symbols used in the following
description of the first embodiment correspond to the numbers and
symbols in FIGS. 1 to 22.
[0085] In the following embodiment, a digital camera will be
described as an example of an imaging device. In the following
description, assuming that the digital camera is in its landscape
orientation, the subject side will be referred to as the "front,"
the opposite side from the subject as the "rear," the vertically
upper side as "upper," the vertically lower side as "lower," the
right side when facing the subject as "right," and the left side
when facing the subject as "left." "Landscape orientation" is a
kind of orientation of a digital camera, and when an image is
captured in landscape orientation, the long-side direction of a
rectangular image that is wider than it is tall substantially
coincides with the horizontal direction within the image.
1. Overall Configuration of Digital Camera
[0086] The configuration of a digital camera 1 will be described
through reference to the drawings. FIG. 1 is an oblique view of the
digital camera 1. FIGS. 2 and 3 are oblique views of a lens barrel
20. In FIG. 2, the lens barrel 20 is shown in its retracted state,
and in FIG. 3, the lens barrel 20 is shown in its wide angle
state.
[0087] As shown in FIG. 1, the digital camera 1 comprises a housing
10 and the lens barrel 20.
[0088] The housing 10 is made up of a front panel 11, a rear panel
12, and a side panel 13. An opening 10S is formed in the front
panel 11.
[0089] The lens barrel 20 comprises a three-stage telescoping zoom
mechanism. The lens barrel 20 is housed in the housing 10 when not
being used for imaging, and is deployed forward from the opening
10S when used for imaging. More specifically, as shown in FIGS. 2
and 3, the lens barrel 20 has a first movable lens barrel part 21,
a second movable lens barrel part 22, a third movable lens barrel
part 23, and a stationary lens barrel part 24.
[0090] The first movable lens barrel part 21 is configured to
deploy with respect to the stationary lens barrel part 24. The
second movable lens barrel part 22 is configured to deploy with
respect to the first movable lens barrel part 21. The third movable
lens barrel part 23 is configured to deploy with respect to the
second movable lens barrel part 22. The stationary lens barrel part
24 is fixed inside the housing 10. As shown in FIG. 3, when the
lens barrel 20 is deployed, the third movable lens barrel part 23
is positioned the farthest forward out of the first to third
movable lens barrel parts 21 to 23.
2. Configuration of Lens Barrel
[0091] Next, the configuration of the lens barrel 20 will be
described through reference to the drawings. FIG. 4 is an exploded
oblique view of the lens barrel 20.
[0092] The first to third movable lens barrel parts 21 to 23 of the
lens barrel 20 are deployed from the stationary lens barrel part 24
along the optical axis AX of the optical system. The optical system
includes first to fifth lens groups L1 to L5. In the following
description, a direction parallel to the optical axis AX will be
called the "optical axis direction," a direction perpendicular to
the optical axis direction will be called the "radial direction,"
and a direction that follows a circle whose center is the optical
axis AX will be called the "peripheral direction." The optical axis
AX substantially coincides with the axis of the various frames that
make up the lens barrel 20.
[0093] As shown in FIG. 4, the lens barrel 20 comprises a
stationary frame 100, a master flange 105, a first rectilinear
frame 110, a second rectilinear frame 120, a third rectilinear
frame 130, a first rotary frame 210, a second rotary frame 220, a
first cosmetic frame 310, a second cosmetic frame 320, a second
lens group frame F2, a third lens group frame F3, a fourth lens
group frame F4, and a fifth lens group frame F5.
[0094] In this embodiment, the stationary frame 100 and the master
flange 105 constitute the stationary lens barrel part 24. The first
rectilinear frame 110 constitutes the third movable lens barrel
part 23. The third rectilinear frame 130, the first rotary frame
210, and the second cosmetic frame 320 constitute the second
movable lens barrel part 22. The second rectilinear frame 120 and
the second rotary frame 220 constitute the first movable lens
barrel part 21.
[0095] The stationary frame 100 is in the form of a cylinder. The
stationary frame 100 has a rectilinear groove a1 and a cam groove
b1 formed in its inner peripheral face. A zoom motor 101 and a zoom
gear 102 are attached to the outer peripheral face of the
stationary frame 100. The zoom motor 101 is a drive source for
deploying the first to third movable lens barrel parts 21 to 23.
The zoom gear 102 transmits the drive force of the zoom motor 101
to the second rotary frame 220.
[0096] The master flange 105 is a flat plastic member that covers
the rear of the stationary frame 100. An imaging element 103 is
fitted in the center of a master flange 244.
[0097] The first rectilinear frame 110 is in the form of a
cylinder, and is disposed on the outside of the first rotary frame
210. The first rectilinear frame 110 has a rectilinear groove a2
and a cam protrusion B2. The rectilinear groove a2 is formed along
the optical axis direction on the inner peripheral face. The cam
protrusion B2 is disposed at the rear end of the inner peripheral
face. The cam protrusion B2 is engaged with a cam groove b2 of the
first rotary frame 210 (discussed below). The first rectilinear
frame 110 supports the first lens group L1 for bringing light into
the lens barrel 20. The first rectilinear frame 110 is covered by
the first cosmetic frame 310.
[0098] The second rectilinear frame 120 is in the form of a
cylinder, and is disposed on the inside of the first rectilinear
frame 110. The second rectilinear frame 120 has a flange 121, a
rectilinear protrusion A1, a bayonet protrusion E1, a rectilinear
protrusion A31, a rectilinear groove a32, and a cam groove b3. The
flange 121 is formed in an annular shape, and is provided to the
rear end part of the outer peripheral face. The rectilinear
protrusion A1 is provided to the outer peripheral face of the
flange 121. The rectilinear protrusion A1 is engaged with the
rectilinear groove a1 of the stationary frame 100. The bayonet
protrusion E1 is provided to the outer peripheral face of the
flange 121. The bayonet protrusion E1 is engaged with a bayonet
groove e1 of the second rotary frame 220 (discussed below). The
rectilinear protrusion A31 is formed on the outer peripheral face
along the optical axis direction. The rectilinear protrusion A31 is
engaged with the rectilinear groove a32 of the third rectilinear
frame 130 (discussed below). The rectilinear groove a32 is formed
in the outer peripheral face along the rectilinear protrusion A31.
A rectilinear protrusion A32 of the third rectilinear frame 130
(discussed below) is engaged with the rectilinear groove a32. The
cam groove b3 is formed in the outer peripheral face so as to
intersect with the optical axis direction.
[0099] The third rectilinear frame 130 is in the form of a
cylinder, and is disposed on the inside of the second rectilinear
frame 120. The third rectilinear frame 130 has a rectilinear
protrusion A2, the rectilinear protrusion A32, a rectilinear groove
a31, a bayonet protrusion E2, a through-groove c1, and a
through-groove c2. The rectilinear protrusion A2 is provided to the
front end part of the outer peripheral face. The rectilinear
protrusion A2 is engaged with the rectilinear groove a2 of the
first rectilinear frame 110. The rectilinear protrusion A32 is
formed in the outer peripheral face along the optical axis
direction. The rectilinear protrusion A32 is engaged with the
rectilinear groove a32 of the second rectilinear frame 120. The
rectilinear groove a31 is formed in the outer peripheral face along
the rectilinear protrusion A32. The rectilinear protrusion A31 of
the second rectilinear frame 120 is engaged with the rectilinear
groove a31. The bayonet protrusion E2 is formed on the outer
peripheral face along the peripheral direction. The bayonet
protrusion E2 is engaged with a bayonet groove e2 of the first
rotary frame 210 (discussed below). The through-groove c1 and the
through-groove c2 pass through the frame main body from the inner
peripheral face to the outer peripheral face, and are formed along
the optical axis direction.
[0100] The first rotary frame 210 is in the form of a cylinder, and
is disposed on the inside of the first rectilinear frame 110. The
first rotary frame 210 has a bayonet protrusion E3, a rectilinear
protrusion A4, a cam protrusion B3, the cam groove b2, a cam groove
b4, and a cam groove b5. The bayonet protrusion E3 is formed at the
rear end part of the outer peripheral face, along the peripheral
direction. The bayonet protrusion E3 is engaged with a bayonet
groove e3 of the second cosmetic frame 320 (discussed below). The
rectilinear protrusion A4 is provided to the outer peripheral face
of the bayonet protrusion E3. The rectilinear protrusion A4 is
engaged with a rectilinear groove a4 of the second rotary frame 220
(discussed below). The cam protrusion B3 is disposed on the inner
peripheral face. The cam protrusion B3 is engaged with the cam
groove b3 of the second rectilinear frame 120. The cam groove b2 is
formed in the outer peripheral face so as to intersect with the
optical axis direction. The cam groove b4 and the cam groove b5 are
formed in the inner peripheral face so as to intersect with the
optical axis direction.
[0101] The second rotary frame 220 is in the form of a cylinder,
and is disposed on the inside of the stationary frame 100. The
second rotary frame 220 has a gear part 221, a cam protrusion B1,
the rectilinear groove a4, and the bayonet groove e1. The gear part
221 is formed at the rear end part of the outer peripheral face,
along the peripheral direction. When the gear part 221 meshes with
a zoom gear 242, the second rotary frame 220 is rotated in the
peripheral direction by the drive force of the zoom motor 101. The
cam protrusion B1 is engaged with the cam groove b1 of the
stationary frame 100. The rectilinear groove a4 is formed in the
inner peripheral face along the optical axis direction. The
rectilinear protrusion A4 of the first rotary frame 210 is engaged
with the rectilinear groove a4. The bayonet groove e1 is formed at
the rear end part of the inner peripheral face, along the
peripheral direction. The bayonet protrusion E1 of the first
rectilinear frame 110 is engaged with the bayonet groove e1.
[0102] The first cosmetic frame 310 covers the front face and the
outer periphery of the first rectilinear frame 110. An opening is
formed in the first cosmetic frame 310 for bringing light in from
the outside. The first lens group L1 is disposed inside the opening
in the first rectilinear frame 110.
[0103] The second cosmetic frame 320 is in the form of a cylinder,
and is disposed on the outside of the first rotary frame 210. The
second cosmetic frame 320 has a rectilinear protrusion A41 and the
bayonet groove e3. The rectilinear protrusion A4 is provided to the
rear end part of the outer peripheral face. The rectilinear
protrusion A41 is engaged with the rectilinear groove a4 of the
second rotary frame 220. The bayonet groove e3 is formed at the
rear end part of the inner peripheral face, along the peripheral
direction. The bayonet protrusion E3 of the first rotary frame 210
is engaged with the bayonet groove e3.
[0104] The second lens group frame F2 is in the form of a disk, and
is disposed on the inside of the third rectilinear frame 130. The
second lens group frame F2 supports a second lens group L2 used for
zooming. The second lens group frame F2 has a cam protrusion B4
that is provided on the outer peripheral face. The cam protrusion
B4 is inserted into the through-groove c1 of the third rectilinear
frame 130, and is engaged with the cam groove b4 of the first
rotary frame 210.
[0105] The third lens group frame F3 has a shutter unit and an OIS
(optical image stabilizer) unit. The shutter unit supports the OIS
unit. The shutter frame is in the form of a cylinder, and is
disposed on the inside of the third rectilinear frame 130. The
third lens group frame F3 has a built-in shutter mechanism. The
third lens group frame F3 has a cam protrusion B5 that is provided
on the outer peripheral face. The cam protrusion B5 is inserted
into the through-groove c2 of the third rectilinear frame 130, and
is engaged with the cam groove b5 of the first rotary frame
210.
[0106] The OIS (optical image stabilizer) unit mainly has an OIS
frame 400 and a refracting lens frame 401.
[0107] The OIS frame 400 is mounted to a shutter frame 335. The OIS
frame 400 is movable within a plane that is perpendicular to the
optical axis. For example, the OIS frame 400 is moved by an
actuator within a plane that is perpendicular to the optical
axis.
[0108] The refracting lens frame 401 is supported by the OIS frame
400 so as to be movable around a refraction shaft that is
substantially parallel to the optical axis. The retracting lens
frame 401 supports a third lens group L3 that is used for image
blur correction. The third lens group L3 is made up of at least one
lens. The position of the refracting lens frame 401 is changed from
a correction enabled position (first orientation) in which the
third lens group L3 executes image blur correction, to a retracted
position (second orientation) in which the third lens group L3 is
retracted from the optical axis.
[0109] The fourth lens group frame F4 is supported by the
stationary frame 100. The fourth lens group frame F4 supports a
fourth lens group L4 that is used for focusing. The fifth lens
group frame F5 is supported by the master flange 105. The fifth
lens group frame F5 supports a fifth lens group L5.
3. Detailed Configuration of Members Constituting the Lens
Barrel
[0110] A summary of the various members was given in "2.
Configuration of Lens Barrel," but here the configuration of the
master flange 105 and the configuration of the third lens group
frame F3 will be described in further detail.
3-1. Master Flange
[0111] As shown in FIG. 5, the master flange 105 has a master
flange main body portion 106 (an example of a first main body
portion), a master flange restrictor 107 (first restrictor), a
first refracting cam 125, and a second retracting cam 126. The
first main body portion 106 is in the form of a disk. The
above-mentioned imaging element 103 is mounted in the center of the
first main body portion 106.
[0112] The first restrictor 107 restricts the movement of the OIS
frame 400. More precisely, the first restrictor 107 engages with an
OIS unit 251 and restricts the movement of the OIS frame 400. More
specifically, the first restrictor 107 engages with an OIS unit 251
and restricts the movement of the OIS frame 400 when the lens
barrel 20 changes from the imaging enabled state to the refracted
state (or when the lens barrel 20 changes from the refracted state
to the imaging enabled state).
[0113] As shown in FIGS. 5 and 6, the first restrictor 107 is
formed integrally with the first main body portion 106. The first
restrictor 107 is constituted by two protrusions 108 that protrude
outward from the first main body portion 106. The two protrusions
108 engage with the OIS frame 400 of the OIS unit 251. As shown in
FIG. 6, the two protrusions 108 come into contact with the inner
peripheral part 120a of the second rectilinear frame 120. This
prevents the two protrusions 108 from falling over.
[0114] A sloped part is formed on the inner peripheral side of the
distal ends of the protrusions 108. These sloped parts guide the
OIS frame 400 from a movable orientation in which the OIS frame 400
is movable (the orientation of the imaging enabled state), to a
movement restricted orientation in which the movement of the OIS
frame 400 is restricted.
[0115] The inner peripheral parts on the proximal end side of the
protrusions (the portion excluding the above-mentioned distal end
(sloped part) and including the middle part) are formed in a planar
shape. The inner peripheral parts are the portions that support the
OIS frame 400 in its movement restricted orientation. In-plane
movement of the OIS frame 400 is reliably restricted by guiding the
OIS frame 400 from the sloped parts on the distal end side to the
inner peripheral part on the proximal end side. The way in which
the in-plane movement of the OIS frame 400 is restricted will be
described in detail in the description of the OIS frame 400
(engagement portion).
[0116] As shown in FIGS. 5 and 7, the first refracting cam 125 is a
portion that is longer in one direction and formed integrally with
the master flange 105. The first refracting cam 125 has a first
guide portion 125a, a second guide portion 125b, and a support
portion 125c.
[0117] The first guide portion 125a comes into contact with a
pressing portion 605 of the refracting lens frame 401, and refracts
the refracting lens frame 401. The first guide portion 125a is a
portion that is formed inclined to the distal end of the first
refracting cam 125.
[0118] In a state in which the first guide portion 125a is in
contact with the pressing portion 605, the OIS frame 400 is guided
by the protrusions 108 from its movable orientation in which the
OIS frame 400 is movable (the orientation of the imaging enabled
state), to an orientation in which the movement of the OIS frame
400 is restricted (movement restricted orientation).
[0119] The second guide portion 125b comes into contact with the
pressing portion 605 of the refracting lens frame 401, and further
refracts the refracting lens frame 401. The second guide portion
125b is formed continuously with the first guide portion 125a, and
is formed at a different angle from that of the first guide portion
125a. In a state in which the second guide portion 125b is in
contact with the pressing portion 605 of the refracting lens frame
401, the OIS frame 400 is in its movement restricted
orientation.
[0120] The support portion 125c is the portion that temporarily
supports the refracting lens frame 401 in its refracted position.
The refracting lens frame 401 is finally positioned by the second
retracting cam 126 (discussed below). The support portion 125c is
formed straight in the optical axis direction. In a state in which
the support portion 125c has come into contact with the pressing
portion 605 of the refracting lens frame 401, the OIS frame 400 is
in its movement restricted orientation.
[0121] The first refracting cam 125 is the portion that finally
positions the retracting lens frame 401. As shown in FIG. 5, the
second refracting cam 126 is formed between the two protrusions
108. The first refracting cam 125 has a sloped part. This sloped
part guides the refracting lens frame 401 to the refracted position
and positions it in the retracted position.
3-2. Third Lens Group Frame
3-2-1. Shutter Unit
[0122] As shown in FIG. 8, a shutter unit 250 is included in the
third lens group frame F3. The shutter unit 250 (an example of a
second frame body) is engaged with the third rectilinear frame 130
and the first rotary frame 210 as mentioned above. Also, the
shutter unit 250 is supported by the master flange 105 (an example
of a first frame body).
[0123] As shown in FIG. 9, the shutter unit 250 has a restrictor
420 (second restrictor) for restricting the movement of the OIS
frame 400, and a second stress dispersion portion 422 (the contact
portion of the shutter unit) that comes into contact with a first
stress dispersion portion 511 (the contact portion of the OIS
frame) of the OIS frame 400 (discussed below). The second stress
dispersion portion 422 is formed in an arc shape having a specific
width. The details of the first stress dispersion portion 511 will
be discussed below.
[0124] The shutter unit 250 further has a step portion 423. The
step portion 423 is formed on the face opposite the OIS frame 400.
When the refracting lens frame 401 has changed its orientation
(position) from the first orientation to the second orientation
(refracted orientation), a housing portion 550 of the retracting
lens frame 401 (discussed below) is disposed at the step portion
423. This affords a more compact size in the optical axis
direction.
3-2-2. OIS Unit
[0125] As shown in FIG. 8, the shutter unit 250 is included in the
third lens group frame F3. The OIS unit 251 is disposed between the
master flange 105 and the shutter unit 250. The OIS unit 251 is
mounted to the shutter unit 250. The OIS unit 251 (an example of a
first unit) has the OIS frame 400 (an example of a support frame),
the refracting lens frame 401, a thrust spring 402 (an example of a
first biasing means), and a rotary spring 403 (an example of a
second biasing means, and an example of a biasing member).
OIS Frame
[0126] The OIS frame 400 (an example of a support frame) is
supported by the shutter unit 250. The OIS frame 400 is configured
to be movable within a plane that is perpendicular to the optical
axis AX, with respect to the shutter unit 250. The OIS frame 400 is
moved by an actuator 520 in a plane that is perpendicular to the
optical axis AX.
[0127] As shown in FIGS. 8 and 10 to 13, the OIS frame 400 has a
main body portion 500 (second main body portion), a refraction
shaft portion 501, an anti-rotation portion 502, at least three
rail portions 503, and engagement portions 504 (see FIGS. 5 and
6).
[0128] As shown in FIG. 8, the second main body portion 500 is
substantially in the form of a disk. The second main body portion
500 has the housing portion 550 for housing the retracting lens
frame 401. The housing portion 550 has two linking portions 550a
that are opposite each other. The linking portions 550a are formed
integrally with the second main body portion 500. More precisely,
the linking portions 550a are formed integrally with the second
main body portion 500 so that the middle between the two linking
portions 550a is disposed in the approximate middle of the shutter
unit 250 in the optical axis direction (the approximate middle in
the thickness direction).
[0129] As shown in FIGS. 8 and 11, the refraction shaft portion 501
is formed on the second main body portion 500. The refraction shaft
portion 501 has a cylindrical part 501a and a refraction shaft
501b. The cylindrical part 501a is formed on the outer peripheral
part of the second main body portion 500. The retraction shaft 501b
is formed on the second main body portion 500. More specifically,
the retraction shaft 501b is formed on the second main body portion
500 so as to protrude toward the inside of the cylindrical part
501a.
[0130] As shown in FIGS. 10 and 12, the anti-rotation portion 502
restricts the movement of the refraction shaft portion 501 produced
by the rotary spring 403. The anti-rotation portion 502 is formed
protruding outward from the second main body portion 500. The
anti-rotation portion 502 has a sloped face 502a. The sloped face
502a is the portion that guides the retracting lens frame 401
toward the OIS frame 400 (the second main body portion 500). The
sloped face 502a is sloped in a state of being opposite the second
main body portion 500. In other words, the sloped face 502a is
sloped with respect to the optical axis AX.
[0131] An example in which the sloped face 502a was sloped at one
angle was given here, but the sloped face 502a may be formed so
that it is sloped in multiple steps. Also, the sloped face 502a may
be formed so that it slopes in the form of a curved surface.
[0132] As shown in FIGS. 10 and 13, at least three rail portions
503 (503a to 503c, for example) are formed on the second main body
portion 500. The rail portions 503 are formed on one face of the
substantially disk-shaped second main body portion 500. The rail
portions 503 are formed on the second main body portion 500 at
positions opposite contact portions 603 (a first contact portion
603A and a second contact portion 603B; discussed below) formed on
the refracting lens frame 401.
[0133] Also, as shown in FIG. 13, the rail portions 503 are formed
on the second main body portion 500 in a portion that excludes a
portion RM where the range over which the third lens group L3
supported by the refracting lens frame 401 moves is projected onto
the second main body portion 500, when the OIS frame 400 is viewed
in the optical axis direction. Furthermore, the rail portions 503
are formed in a shape that corresponds to the path over when the
contact portions 603 (the first contact portion 603A and the second
contact portion 603B; discussed below) move when the lens barrel 20
changes from its imaging enabled state to its refracted state.
[0134] As discussed above, the engagement portions 504 engage with
the first restrictor 107 formed on the master flange 105, such as
the two protrusions 108 (see FIGS. 5 and 6). As shown in FIGS. 10
and 14, the engagement portions 504 are formed integrally with the
second main body portion 500. More specifically, the engagement
portions 504 are portions that protrude outward from the outer
peripheral part of the second main body portion 500. These two
engagement portion 504 respectively engage with the two protrusions
108 of the master flange 105. More specifically, the engagement
portions 504 are pressed by the protrusions 108 of the master
flange 105. This restricts the in-plane movement of the OIS frame
400.
[0135] More precisely, as shown in FIG. 6, when the lens barrel 20
changes from its imaging enabled state to its refracted state, the
OIS frame 400 moves in the optical axis direction with respect to
the shutter unit 250. The two protrusions 108 of the master flange
105 then respectively engage with the two protrusions of the OIS
frame 400, which restricts the in-plane movement of the OIS frame
400. More precisely, first the engagement portions 504 respectively
come into contact with the sloped faces formed on the inner
peripheral side of the distal ends of the protrusions 108, such as
the inner peripheral side of the distal ends of the protrusions
108. Next, the engagement portions 504 come into contact with the
inner peripheral parts on the proximal end side of the protrusions
108 (the portion excluding the distal ends and including the
middle). This guides the OIS frame 400 from the above-mentioned
movable orientation to the movement restricted orientation, and
restricts the in-plane movement of the OIS frame 400 in the
movement restricted orientation.
[0136] In the overall configuration, when the lens barrel 20
changes from its imaging enabled state to its refracted state, the
shutter unit 250 and the OIS unit 251 move in the optical axis
direction with respect to the master flange 105. This movement of
the shutter unit 250 and the OIS unit 251 in the optical axis
direction causes the master flange 105 to engage with the OIS frame
400 as discussed above, and restricts the in-plane movement of the
OIS frame 400.
[0137] As shown in FIG. 14, the OIS frame 400 further has a
restricted portion 510 and the first stress dispersion portion 511.
The restricted portion 510 is the portion that receives the
restrictor 420 of the shutter unit 250. Here, when the restrictor
420 is disposed in the interior of the restricted portion 510, the
movement of the second main body portion 500 in the optical axis
direction is restricted with respect to the shutter unit 250.
Meanwhile, the OIS frame 400 is movable within the plane that is
perpendicular to the optical axis AX with respect to the shutter
unit 250.
[0138] The first stress dispersion portion 511 is the portion that
comes into contact with the shutter unit 250 when the pressing
portion 605 of the refracting lens frame 401 (discussed below) is
pressed. The first stress dispersion portion 511 is provided to the
OIS frame 400 at a position closer to the pressing portion 605 than
the restricted portion 510. The first stress dispersion portion 511
is formed in an arc shape having a specific width. Here, the width
of the first stress dispersion portion 511 is less than the width
of the second stress dispersion portion 422. However, the second
stress dispersion portion 422 may be formed so that its width
becomes less than the width of the first stress dispersion portion
511.
[0139] As shown in FIGS. 10 and 11, the OIS frame 400 further has
an anti-detachment portion 530 (restrictor of the OIS frame 400).
The anti-detachment portion 530 is the portion that restricts
detachment of the retracting lens frame 401 from the OIS frame 400
(the second main body portion 500). The anti-detachment portion 530
is formed integrally with the refraction shaft portion 501. The
anti-detachment portion 530 is provided a specific distance away
from the second main body portion 500. The anti-detachment portion
530 is formed near the refraction shaft 501b.
Retracting Lens Frame
[0140] The refracting lens frame 401 supports at least one lens. As
shown in FIGS. 15A and 15B, the retracting lens frame 401 supports
the third lens group L3, which is made up of four lenses. The
retracting lens frame 401 is supported by the OIS frame 400 (see
FIG. 10). The refracting lens frame 401 moves around the refraction
shaft 501b, which is substantially parallel to the optical axis AX,
when retracting. Consequently, the retracting lens frame 401 is
disposed at a position that is shifted from the optical axis AX
during refraction.
[0141] As shown in FIGS. 15A and 15B, the refracting lens frame 401
moves around the refraction shaft 501b (axis JX) that is
substantially parallel to the optical axis AX, when the lens barrel
20 changes from its imaging enabled state to its refracted state.
More precisely, the position of the retracting lens frame 401
changes from a first orientation in which the third lens group L3
executes shake correction, to a second orientation in which the
third lens group L3 is refracted from the optical axis AX, when the
lens barrel 20 changes from its imaging enabled state to its
refracted state.
[0142] As shown in FIGS. 16 and 17, the refracting lens frame 401
has a main body portion 600 (third main body portion 600) of the
refracting lens frame 401, a shaft support 601 (an example of a
bearing), a lens support 602, and the plurality of contact portions
603 (603A to 603C). The shaft support 601 is the portion that
engages with the above-mentioned retraction shaft 501b (see FIG.
11). The shaft support 601 rotatably supports the refraction shaft
501b. The shaft support 601 is a hole into which the refraction
shaft 501b is inserted, and this hole is formed in the third main
body portion 600.
[0143] As shown in FIG. 17, the shaft support 601 (hole) has at
least two contact faces 601a that come into contact with the
refraction shaft 501b. More precisely, the two contact faces 601a
are formed on the inner peripheral face of the shaft support 601.
The two contact faces 601a are formed on the shaft support 601 on
the proximal end side of the refraction shaft 501b, that is, on the
opening side of the shaft support 601 (hole) (see FIG. 11). The two
contact faces 601a are formed on the inner peripheral face of the
shaft support 601 so as to be in a mutually non-parallel relation.
More specifically, when viewed in the depth direction, the shaft
support 601 (hole) is formed in the inner peripheral face of the
shaft support 601 so that the two contact faces 601a are at an
angle.
[0144] As shown in FIG. 17A, the two contact faces 601a
(hereinafter referred to as V-faces) come into contact with the
outer peripheral face of the refraction shaft 501b. More
specifically, as shown in FIG. 17A, the refracting lens frame 401
is biased by the biasing force F0 of the rotary spring 403, and the
component force F1 of this biasing force F0 causes the V-faces 601a
formed on the shaft support 601 of the retracting lens frame 401 to
come into contact with the outer peripheral face of the refraction
shaft 501b. This allows the retraction shaft 501b to be positioned
accurately with respect to the shaft support 601 of the refracting
lens frame 401. More precisely, precision with respect to the
eccentricity of the refraction shaft 501b can be improved. In FIG.
17A, F1 and F2 are components of the biasing force F0.
[0145] The lens support 602 shown in FIG. 16 is the portion that
supports the third lens group L3 (four lenses). The lens support
602 is substantially in cylindrical in form, and supports the third
lens group L3 on its inner peripheral part. In a state in which the
retracting lens frame 401 has been mounted to the shutter unit 250,
the lens support 602 is disposed in the approximate middle of the
shutter unit 250 in the optical axis direction (the approximate
middle in the thickness direction).
[0146] The plurality of contact portions 603 shown in FIG. 16 are,
for example, made up of three first contact portions 603A (603A1,
603A2, and 603A3), the second contact portion 603B, and a third
contact portion 603C. The three first contact portions 603A, the
second contact portion 603B, and the third contact portion 603C are
formed on the third main body portion 600 at different positions
from the shaft support 601. In other words, the three first contact
portions 603A, the second contact portion 603B, and the third
contact portion 603C are formed on the third main body portion 600
at different positions from the refraction shaft 501b supported by
the shaft support 601. Also, the three first contact portions 603A,
the second contact portion 603B, and the third contact portion 603C
are formed on the third main body portion 600 at different
positions from the refraction shaft 501b so as to allow contact
with the OIS frame 400.
[0147] More precisely, two of the contact portions 603A1 and 603A2
of the three first contact portions 603A, and the second contact
portion 603B are formed on the third main body portion 600 near the
refraction shaft 501b. The two contact portions 603A1 and 603A2 are
formed on the third main body portion 600 so that the refraction
shaft 501b is positioned between these two contact portions 603A1
and 603A2.
[0148] The second contact portion 603B is formed on the third main
body portion 600 so that the refraction shaft 501b is positioned
between one of the two contact portions 603A1 and 603A2 and the
second contact portion 603B. Also, the other first contact portion
603A3 besides these two contact portions 603A1 and 603A2, and the
third contact portion 603C are formed on the third main body
portion 600 at positions that are away from the refraction shaft
501b.
[0149] As shown in FIG. 16, a specific first contact portion 603A
(603A3) is formed on the third main body portion 600 so that the
angle formed by a first line segment LN1 that connects the optical
axis AX of the third lens group L3 supported by the lens support
602 to a specific first contact portion 603A, and a second line
segment LN2 that connects the optical axis AX of the third lens
group L3 supported by the lens support 602 to the retraction shaft
501b becomes an obtuse angle. The "specific first contact portion
603A" is at least one contact portion from among the three first
contact portions 603A. Here, the first contact portion 603A3 formed
at the position farthest away from the refraction shaft 501b
corresponds to the specific first contact portion.
[0150] In other words, the first contact portion formed at the
position farthest away from the refraction shaft 501b is formed on
the third main body portion 600 so that a specific straight line
LN3 is disposed between the retraction shaft 501b and the
above-mentioned specific first contact portion 603A. The specific
straight line LN3 passes through the optical axis AX of the third
lens group L3 supported by the lens support 602, and is
perpendicular to the second line segment LN2 that connects the
refraction shaft 501b to the optical axis AX of the third lens
group L3 supported by the lens support 602.
[0151] As shown in FIG. 18, at least one of the three first contact
portions 603A (603A1, 603A2, and 603A3), the second contact portion
603B, and the third contact portion 603C is formed on the third
main body portion 600 so as to overlap the third lens group L3 in a
direction perpendicular to the optical axis AX. In other words, at
least one of the three first contact portions 603A, the second
contact portion 603B, and the third contact portion 603C is
provided to the refracting lens frame 401 so as to overlap the
third lens group L3 within a range D of the thickness of the third
lens group L3. Here, the three first contact portions 603A, the
second contact portion 603B, and the third contact portion 603C are
provided to the refracting lens frame 401 so as to overlap the
third lens group L3 in a direction perpendicular to the optical
axis AX within the range D of the thickness of the third lens group
L3.
[0152] Here, at least three of the three first contact portions
603A (603A1, 603A2, and 603A3), the second contact portion 603B,
and the third contact portion 603C is configured to come into
contact with the OIS frame 400. Specifically, if at least three
contact portions out of the three first contact portions 603A and
the second contact portion 603B come into contact with the OIS
frame 400, this restricts the movement of the retracting lens frame
401 in the optical axis direction.
[0153] More precisely, if at least three contact portions out of
the three first contact portions 603A and the second contact
portion 603B come into contact with the rail portions 503 of the
OIS frame 400 (see FIG. 14), this restricts the movement of the
refracting lens frame 401 in the optical axis direction. More
specifically, when the lens barrel 20 is in its imaging enabled
state, the three first contact portions 603A1, 603A2, and 603A3
respectively come into contact with the rail portions 503a, 503b,
and 503c of the OIS frame 400. Here, the first contact portion
603A1 comes into contact with the rail portion 503a, the first
contact portion 603A2 comes into contact with the rail portion
503b, and the first contact portion 603A3 comes into contact with
the rail portion 503c. In this case, the second contact portion
603B does not come into contact with the rail portions 503.
[0154] On the other hand, when the lens barrel 20 is in its
refracted state, the two first contact portions 603A2 and 603A3 and
the second contact portion 603B respectively come into contact with
the rail portions 503a, 503b, and 503c of the OIS frame 400. Here,
when the lens barrel 20 has changed from the imaging enabled state
to the refracted state, one of the three first contact portions
603A, such as the first contact portion 603A1, separates from the
rail portion 503, and the second contact portion 603B comes into
contact with that rail portion 503. Thus having at least three
contact portions out of the three first contact portions 603A and
the second contact portion 603B come into contact with the rail
portions 503 of the OIS frame 400 reliably restricts the movement
of the refracting lens frame 401 in the optical axis direction.
[0155] The third contact portion 603C comes into contact with the
OIS frame 400 when the lens barrel 20 changes from the imaging
enabled state to the refracted state. This will be discussed in
detail below.
[0156] As shown in FIG. 16, the refracting lens frame 401 further
has the pressing portion 605 and an engagement portion 606. The
pressing portion 605 is the portion that is pressed when the
refracting lens frame 401 changes from the imaging enabled state to
the refracted state. More precisely, when the refracting lens frame
401 changes from the imaging enabled state to the refracted state,
the pressing portion 605 is pressed by the first refracting cam 125
and the second refracting cam 126 provided to the master flange
(see FIG. 5). When the pressing portion 605 is thus pressed, the
load exerted on the restrictor 420 and the restricted portion 510
is limited by allowing the first stress dispersion portion 511
(FIG. 14) and the second stress dispersion portion 422 (see FIG. 9)
to come into contact with each other.
[0157] The engagement portion 606 is the portion that engages with
the anti-detachment portion 530. At the refracting lens frame 401,
if the engagement portion 606 is disposed between the second main
body portion 500 (the main body portion of the OIS frame 400) and
the anti-detachment portion 530 (see FIG. 11), detachment of the
refracting lens frame 401 in the optical axis direction is
restricted. As shown in FIG. 16, the engagement portion 606 is
formed integrally with the shaft support 601. The engagement
portion 606 is formed in an arc shape. A cut-out 606c is formed in
the engagement portion 606. The engagement portion 606 is disposed
between the anti-detachment portion 530 and the third main body
portion 600 by introducing the anti-detachment portion 530 into the
cut-out 606c.
Thrust Spring
[0158] The thrust spring 402 is a spring that biases the retracting
lens frame 401 with respect to the OIS frame 400. As shown in FIGS.
8 and 11, the thrust spring 402 is mounted to the OIS frame 400
and/or the retracting lens frame 401.
[0159] The thrust spring 402 has a pair of opposing parts 440 and a
linking portion 441 that links the two opposing parts 440. One of
the two opposing parts 440 (the first opposing part 440a) is
mounted to the OIS frame 400, and the other opposing part 440 (the
second opposing part 440b) is mounted to the retracting lens frame
401. More precisely, as shown in FIG. 11, in a state in which the
retraction shaft 501b of the OIS frame 400 is supported by the
shaft support 601 of the retracting lens frame 401, the first
opposing part 440a is mounted to the OIS frame 400, and the second
opposing part 440b is mounted to the refracting lens frame 401.
Consequently, the thrust spring 402 clamps the OIS frame 400 and
the refracting lens frame 401.
[0160] Consequently, the thrust spring 402 brings at least two of
the contact portions 603 into contact with the OIS frame 400. Here,
the thrust spring 402 brings at least two of the contact portions
out of the two first contact portions 603A (603A1 and 603A2) and
the second contact portion 603B formed near the retraction shaft
501b (the shaft support 601) into contact with the OIS frame
400.
Rotary Spring
[0161] The rotary spring 403 is a spring that biases the refracting
lens frame 401 around the refraction shaft 501b. The rotary spring
403 shown in FIG. 8 is supported by the OIS frame 400. The rotary
spring 403 is a torsion coil spring, for example. As shown in FIGS.
11 and 17B, a portion 403c of the coil of the rotary spring 403
(the coil part) is mounted around the outside of the cylindrical
part 501a of the refraction shaft portion 501. One end 403a of the
rotary spring 403 is mounted in a groove 444 formed in the OIS
frame 400. The other end 403b of the rotary spring 403 is mounted
in a groove 445 formed in the retracting lens frame 401.
[0162] When the rotary spring 403 biases the refracting lens frame
401, the third contact portion 603C of the refracting lens frame
401 comes into contact with the sloped face 502a of the OIS frame
400. The third contact portion 603C is then guided by the sloped
face 502a, and the refracting lens frame 401 approaches the OIS
frame 400. This positions the retracting lens frame 401 with
respect to the OIS frame 400. In this state, the first contact
portion 603A3 is in contact with the OIS frame 400.
[0163] As shown in FIG. 17b, in this embodiment, when the rotary
spring 403 is viewed in the center axis direction of the coil part
403c, the other end 403B of the rotary spring 403 is in the form of
a straight line. Instead, as shown in FIG. 17C, the distal end
403b2 of the other end 403B of the rotary spring 403 may be bent
with respect to the proximal end 403b1 (the portion near the coil
part 403c).
[0164] More specifically, using the proximal end 403b1 of the
rotary spring 403 as a reference, the distal end 403b2 of the
rotary spring 403 is bent. In other words, using the proximal end
403b1 as a reference, the distal end 403b2 is bent in the rotation
direction of the retracting lens frame 401. Even more specifically,
using the proximal end 403b1 as a reference, the distal end 403b2
is bent so as to move closer to the coil part 403c.
[0165] In this case, a spring receiver 607 is formed on the
retracting lens frame 401, and the distal end 403b2 of the other
end 403B of the rotary spring 403 comes into contact with this
spring receiver 607.
[0166] As a result of this configuration, as shown in FIG. 17C, the
component force F1' of the biasing force F0' of the rotary spring
403 causes the V-faces 601a formed in the shaft support 601 of the
retracting lens frame 401 to come into contact with the outer
peripheral face of the refraction shaft 501b. In FIG. 17C, the
component force F1' at which the V-faces 601a of the retracting
lens frame 401 are brought into contact with the outer peripheral
face of the refraction shaft 501b is greater than that in FIG. 17B
(F1'>F1). Consequently, the refraction shaft 501b is positioned
more reliably with respect to the shaft support 601 of the
retracting lens frame 401. More precisely, accuracy with respect to
the eccentricity of the refraction shaft 501b can be improved more
reliably. In FIG. 17C, F1' and F2' are components of the biasing
force F0'.
[0167] The amount and direction of the component force F1' by which
the V-faces 601a are biased toward the refraction shaft vary with
the position where the V-faces are formed. Specifically, the
bending of the rotary spring 403 and the formation position of the
V-faces 601a in FIG. 17B are just examples given to illustrate this
technology. Therefore, the bending of the rotary spring 403 is not
limited to how it is done in this embodiment, and any way is fine
as long as the component force F1' by which the V-face are biased
toward the refraction shaft can be increased.
3-3. Actuator
[0168] The actuator 520 is mounted to the third lens group frame
F3. More precisely, as shown in FIG. 19, the actuator 520 is
disposed on the third lens group frame F3, using an effective
imaging range YR as a reference. The effective imaging range YR is
defined by the imaging element 103 mounted to the master flange
105. In this embodiment, the effective imaging range YR is formed
in a rectangular shape.
[0169] As shown in FIG. 19, the actuator 520 has a first actuator
521 and a second actuator 522. The first actuator 521 moves the OIS
frame 400 in a short-side direction T1 (first direction) of the
effective imaging range YR. The first actuator 521 is disposed on
one short side of the effective imaging range YR. The first
actuator 521 is made up of a magnet 521a and a coil 521b. The
magnet 521a is mounted to the OIS frame 400, and the coil 521b is
mounted to the shutter unit 250 at a position opposite the magnet
521a.
[0170] As shown in FIG. 19, the second actuator 522 moves the OIS
frame 400 in a long-side direction T2 (second direction) of the
effective imaging range YR. The second actuator 522 is larger than
the first actuator 521. The second actuator 522 is disposed on one
long side of the effective imaging range YR. More specifically, the
second actuator 522 is disposed on the lower long side of the
effective imaging range YR. The second actuator 522 is made up of a
magnet 522a and two coils 522b. The magnet 522a is mounted to the
OIS frame 400, and the two coils 522b are mounted to the shutter
unit 250 at a position opposite the magnet 522a. The retracting
lens frame 401 moves along the other long side of the effective
imaging range YR (such as the upper long side).
[0171] In this state, when power is supplied from a camera circuit
(not shown) to the coils 521b and 522b of the shutter unit 250,
current flows and a magnetic field is generated in the coils 521b
and 522b. This magnetic field drives the magnets 521a and 522a of
the OIS frame 400, and this drive force causes the OIS frame 400 to
move in a plane that is perpendicular to the optical axis AX. More
precisely, the OIS frame 400 is moved by the first actuator 521 in
the short-side direction, and is moved by the second actuator 522
in the long-side direction.
4. Engagement of Frames
[0172] FIGS. 5 to 7 are cross sections of the lens barrel 20.
However, FIGS. 5 to 7 are simplified diagrams that combine a
plurality of cross sections passing through the optical axis AX. In
FIG. 5 the lens barrel 20 is shown in its refracted state, in FIG.
6 the lens barrel 20 is shown in its wide angle state, and in FIG.
7 the lens barrel 20 is shown in its telephoto state.
[0173] As shown in FIG. 5, in the retracted state, the second
rotary frame 220, the second cosmetic frame 320, the first cosmetic
frame 310, the first rectilinear frame 110, the first rotary frame
210, the second rectilinear frame 120, and the third rectilinear
frame 130 are housed in that order on the inside in the radial
direction of the stationary frame 100. Also, in the retracted
state, the third lens group L3 refracts outward in the radial
direction of the fourth and fifth lens groups L4 and L5, which
allows the lens barrel 20 to be more compact in the optical axis
direction.
[0174] The engagement of the frames will now be described through
reference to FIGS. 6 and 7.
[0175] The gear part 221 of the second rotary frame 220 meshes with
the zoom gear 102 (not shown). The cam protrusion B1 of the second
rotary frame 220 is engaged with the cam groove b1 of the
stationary frame 100. Consequently, the second rotary frame 220
moves in the optical axis direction while rotating in the
peripheral direction under the drive force of the zoom motor
101.
[0176] The rectilinear protrusion A1 of the second rectilinear
frame 120 is engaged with the rectilinear groove a1 of the
stationary frame 100. The bayonet protrusion E1 of the second
rectilinear frame 120 is engaged with the bayonet groove e1 of the
second rotary frame 220. Therefore, the second rectilinear frame
120 moves in the optical axis direction along with the second
rotary frame 220.
[0177] The rectilinear protrusion A4 of the first rotary frame 210
is engaged with the rectilinear groove a4 of the first rotary frame
210. The cam protrusion B3 of the first rotary frame 210 is engaged
with the cam groove b3 of the second rectilinear frame 120.
Therefore, the first rotary frame 210 moves in the optical axis
direction along with the second rectilinear frame 120 while
rotating in the peripheral direction along with the first rotary
frame 210.
[0178] The cam protrusion B2 of the first rectilinear frame 110 is
engaged with the cam groove b2 of the first rotary frame 210. The
rectilinear protrusion A2 of the third rectilinear frame 130 is
engaged with the rectilinear groove a2 of the first rectilinear
frame 110. Therefore, the first rectilinear frame 110 moves in the
optical axis direction according to the rotation of the first
rotary frame 210.
[0179] The bayonet protrusion E2 of the third rectilinear frame 130
is engaged with the bayonet groove e2 of the second rotary frame
220. The rectilinear protrusion A2 of the third rectilinear frame
130 is engaged with the rectilinear groove a2 of the first
rectilinear frame 110. Therefore, the third rectilinear frame 130
moves in the optical axis direction along with the first rotary
frame 210.
[0180] As discussed above, the first rotary frame 210 is engaged
with the first rectilinear frame 110 via a cam mechanism, and
rotates to move the first rectilinear frame 110 rectilinearly.
Also, the second rectilinear frame 120 is engaged with the first
rotary frame 210 via a cam mechanism, and moves rectilinearly in
the optical axis direction to rotate the first rotary frame 210.
Accordingly, the first rotary frame 210 is moved by moving the
second rectilinear frame 120 rectilinearly while moving the first
rectilinear frame 110 rectilinearly by rotating the first rotary
frame 210, by rotating the second rotary frame 220 with the zoom
motor 101. As a result, the first to third movable lens barrel
parts 21 to 23 are deployed smoothly from the stationary lens
barrel part 24.
5. Operation of OIS Unit
[0181] Finally, the operation of the OIS unit will be described on
the basis of the configuration of the lens barrel 20 discussed
above.
[0182] First, as shown in FIG. 15A, in the imaging enabled state,
the third contact portion 603C of the refracting lens frame 401
comes into contact with the anti-rotation portion 502, which
positions the retracting lens frame 401 with respect to the OIS
frame 400 in the first orientation (imaging enabled
orientation).
[0183] Next, when the lens barrel 20 starts changing from its
imaging enabled state to its refracted state, the shutter unit 250
approaches the master flange 105 as shown in FIG. 6. The engagement
portions 504 of the OIS frame 400 mounted to the shutter unit 250
then come into contact with the distal ends of the protrusions 108
provided to the master flange 105. The distal ends of the
protrusions 108 then press on the OIS frame 400. Once the
engagement portions 504 of the OIS frame 400 come into contact with
the inner peripheral part of the protrusions 108 (the portion more
to the proximal end side than the distal end), movement of the OIS
frame 400 with respect to the shutter unit 250 is restricted.
[0184] Meanwhile, in a state in which the OIS frame 400 is being
pressed by the protrusions 108 of the master flange 105, the
pressing portion 605 of the refracting lens frame 401 is pressed
and guided by the first refracting cam 125 provided to the master
flange 105.
[0185] More precisely, in a state in which the OIS frame 400 is
being pressed by the distal ends of the protrusions 108, the
pressing portion 605 of the refracting lens frame 401 comes into
contact with and is guided by the first guide portion 125a of the
first refracting cam 125 (see FIG. 7), causing the retracting lens
frame 401 to start retracting from the first orientation toward the
second orientation (refracted orientation).
[0186] Then, in a state in which the OIS frame 400 is being pressed
by the inner peripheral part on the proximal end side of the
protrusions 108 (the portion excluding the distal ends and
including the middle), the pressing portion 605 of the refracting
lens frame 401 comes into contact with and is guided by the second
guide portion 125b of the first refracting cam 125 (see FIG. 7),
causing the refracting lens frame 401 to retract further. The
pressing portion 605 of the refracting lens frame 401 then comes
into contact with the support portion 125c of the first refracting
cam 125 (see FIG. 7).
[0187] Finally, when the shutter unit 250 further approaches the
master flange 105, a positioning portion 609 provided to the
retracting lens frame 401 comes into contact with the second
refracting cam 126. This positions the retracting lens frame 401 in
the refracted position.
[0188] Here, the direction in which the protrusions 108 of the
master flange 105 press on the engagement portions 504 of the OIS
frame 400 is substantially the same as the direction in which the
first retracting cam 125 of the master flange 105 presses on the
pressing portion 605 of the refracting lens frame 401. In other
words, the protrusions 108 of the master flange 105 and the first
retracting cam 125 of the master flange 105 press on the engagement
portions 504 of the OIS frame 400 and the first refracting cam 125
of the refracting lens frame 401 in the direction in which the OIS
frame 400 approaches the shutter unit 250. Thus pressing the
engagement portions 504 of the OIS frame 400 and the first
retracting cam 125 of the refracting lens frame 401 in
substantially the same direction allows the refracting lens frame
401 to be positioned reliably.
[0189] Thus, the movement of the OIS frame 400 with respect to the
shutter unit 250 is restricted, and the refracting lens frame 401
is positioned with respect to the OIS frame 400 in the second
orientation (refracted orientation). At this point, the lens
support 602 of the retracting lens frame 401 is housed in the
housing portion 550 of the OIS frame 400.
[0190] Thus, with this lens barrel 20, when the lens barrel 20
changes from its imaging enabled state to its refracted state, the
restriction of movement of the OIS frame 400 and the positioning of
the refracting lens frame 401 are executed simultaneously.
Specifically, the lens barrel 20 of this embodiment retracts the
third lens group L3 used for OIS. Here again, movement of the OIS
frame 400 itself is restricted with a restricting mechanism that
restricts the movement of the OIS frame 400 (e.g., the relation
between the inner peripheral part of the protrusions 108 and the
engagement portions 504 of the OIS frame 400), before the third
lens group L3 is refracted with a refracting mechanism (e.g., the
relation between the pressing portion 605 of the refracting lens
frame 401 and the first refracting cam 125 provided to the master
flange 105). This allows the third lens group L3 to be retracted
more reliably.
6. Action and Effect
[0191] (1) This lens barrel 20 comprises the master flange 105, the
shutter unit 250, the OIS frame 400, and the refracting lens frame
401. The shutter unit 250 is supported by the master flange 105.
The OIS frame 400 is supported by the shutter unit 250, and is
movable within a plane that is perpendicular to the optical axis
with respect to the shutter unit 250. The refracting lens frame 401
is supported by the OIS frame 400, and moves around the refraction
shaft 501b, which is substantially parallel to the optical axis,
during the transition period between the imaging enabled state and
the housed state. The shutter unit 250, the OIS frame 400, and the
refracting lens frame 401 move in the optical axis direction with
respect to the master flange 105 during the transition period
between the imaging enabled state and the housed state. The master
flange 105 restricts in-plane movement of the OIS frame 400 during
the transition period between the imaging enabled state and the
housed state.
[0192] With this lens barrel 20, the master flange 105 restricts
in-plane movement of the OIS frame 400 during the transition period
between the imaging enabled state and the housed state.
Consequently, in the housed state, there is no need to provide
clearance or the like for avoiding contact with members caused by
in-plane movement of the OIS frame 400, so the lens barrel 20 can
be more compact.
[0193] (2) With this lens barrel 20, the master flange 105 has the
first restrictor 107 that restricts the movement of the OIS frame
400 during the transition period between the imaging enabled state
and the housed state. The OIS frame 400 has the engagement portions
504 that engages with the first restrictor 107.
[0194] With this lens barrel 20, when the first restrictor 107 of
the master flange 105 engages with the engagement portions 504 of
the OIS frame 400, in-plane movement of the OIS frame 400 is
restricted by the master flange 105 during the transition period
between the imaging enabled state and the housed state.
Consequently, there is no need to provide the above-mentioned
clearance, etc., so the lens barrel can be more compact.
[0195] (3) With this lens barrel 20, the first restrictor 107 is a
first protrusion that is provided to the master flange 105 and
protrudes in the optical axis direction. The engagement portions
504 is a second protrusion that is provided protruding from the
outer peripheral part of the OIS frame 400 and comes into contact
with the first protrusion.
[0196] With this lens barrel, the first restrictor 107 protrudes in
the optical axis direction from the master flange 105, and the
engagement portions 504 protrudes from the outer peripheral part of
the OIS frame 400. With this configuration, the master flange 105
can reliably restrict the in-plane movement of the OIS frame 400
during the transition period between the imaging enabled state and
the housed state.
[0197] (4) With this lens barrel 20, the master flange 105
restricts the in-plane movement of the OIS frame 400 and retracts
the retracting lens frame 401. Specifically, the restriction of the
in-plane movement of the OIS frame 400 and the retraction of the
retracting lens frame 401 can be accomplished with a single member
(the master flange 105), so this improves accuracy during in-plane
restriction of the OIS frame 400 and accuracy during retraction of
the retracting lens frame 401.
Second Embodiment
[0198] Next, a second embodiment of the present technology will be
described through reference to FIGS. 23 to 32. The numbers and
symbols used in the following description of the second embodiment
correspond to the numbers and symbols in FIGS. 23 to 32.
Detailed Configuration of Lens Barrel 20
[0199] First, the detailed configuration of the lens barrel 20 will
be described through reference to the drawings. FIG. 23 is an
oblique view of the lens barrel 20, and FIG. 24 is an exploded
oblique view of the lens barrel 20.
[0200] The lens barrel 20 comprises a three-stage telescoping zoom
mechanism. As shown in FIGS. 23 and 24, the lens barrel 20 has the
first movable lens barrel part 21, the second movable lens barrel
part 22, the third movable lens barrel part 23, and the stationary
lens barrel part 24.
1. First Movable Lens Barrel Part 21
[0201] The first movable lens barrel part 21 has the first
rectilinear frame 110, the first rotary frame 210, and first
cosmetic frame 301. The first rectilinear frame 110 is a
cylindrical plastic member disposed on the inside in the radial
direction of the stationary frame 100 (discussed below). The first
rotary frame 210 is a cylindrical plastic member disposed on the
inside in the radial direction of the stationary frame 100. The
first cosmetic frame 301 is a cylindrical sheet metal member that
covers the outer periphery of the first rectilinear frame 110.
2. Second Movable Lens Barrel Part 22
[0202] The second movable lens barrel part 22 has the second
rectilinear frame 120, the second rotary frame 220, the third
rectilinear frame 130, the second cosmetic frame 320, the second
lens group L2, a third lens group frame 330, the third lens group
L3, the shutter frame 335, and a second cosmetic frame 302.
[0203] The second rectilinear frame 120 is a cylindrical plastic
member disposed on the inside in the radial direction of the first
rotary frame 210. The second rotary frame 220 is a cylindrical
plastic member disposed on the inside in the radial direction of
the second rectilinear frame 120.
[0204] The third rectilinear frame 130 is a cylindrical plastic
member disposed on the inside in the radial direction of the second
rotary frame 220. The second cosmetic frame 320 is disposed on the
inside in the radial direction of the third rectilinear frame 130,
and supports the second lens group L2 used for zooming. The third
lens group frame 330 is housed in the shutter frame 335 and
supports the third lens group L3 used for image blur correction.
The third lens group frame 330 is supported by the shutter frame
335 pivotably in the radial direction, and along with the third
lens group L3 constitutes an image blur correction mechanism.
[0205] The shutter frame 335 is disposed on the inside in the
radial direction of the third rectilinear frame 130, and has a
built-in shutter mechanism. The shutter frame 335 supports the
third lens group frame 330 pivotably in the radial direction. A
control-use flexible wire 335a is connected to the shutter frame
335.
[0206] The control-use flexible wire 335a is disposed along the
inner peripheral face of the stationary frame 100, and is connected
to a control device (not shown). The control-use flexible wire 335a
transmits control signals to the shutter mechanism or image blur
correction mechanism (discussed below). The second cosmetic frame
302 is a cylindrical sheet metal member that covers the outer
periphery of the second rectilinear frame 120.
3. Third Movable Lens Barrel Part 23
[0207] The third movable lens barrel part 23 has the first cosmetic
frame 310, the first lens group L1, and a third cosmetic frame
303.
[0208] The first cosmetic frame 310 is disposed between the second
rectilinear frame 120 and the second rotary frame 220. The first
cosmetic frame 310 supports the first lens group L1, which is used
to bring light into the lens barrel 20. The third cosmetic frame
303 is a cylindrical sheet metal member that covers the outer
periphery of the first cosmetic frame 310.
4. Stationary Lens Barrel Part 24
[0209] The stationary lens barrel part 24 has the stationary frame
100, a fourth lens group frame 340, the fourth lens group L4, a
zoom motor 241, the zoom gear 242, a focus motor 243, the master
flange 244, an imaging element 245, and imaging element flexible
wire 245a.
[0210] The stationary frame 100 is a cylindrical plastic member
disposed on the outside in the radial direction of the first rotary
frame 210. The fourth lens group frame 340 is attached to the
master flange 244 and is driven in the optical axis direction by
the focus motor 243. The fourth lens group frame 340 supports the
fourth lens group L4 used for focal adjustment.
[0211] The zoom motor 241 is a drive source for deploying the first
to third movable lens barrel parts 21 to 23, and is attached to the
side face of the stationary frame 100. The zoom gear 242 transmits
the drive force of the zoom motor 241 to the first rotary frame
210. The front end of the zoom gear 242 is supported by the
stationary frame 100, and the rear end of the zoom gear 242 is
supported by the master flange 244. The focus motor 243 is a drive
source for driving the fourth lens group frame 340 in the optical
axis direction, and is attached to the master flange 244. The
master flange 244 is a flat plastic member that covers the rear of
the stationary frame 100. The imaging element 245 is fitted in the
center of the master flange 244. The imaging element flexible wire
245a is affixed to the rear face of the master flange 244. The
imaging element flexible wire 245a is connected to a control device
(not shown), and transmits signals from the imaging element
245.
5. Engagement of Frames
[0212] FIGS. 25 to 27 are cross sections of the lens barrel 20.
However, FIGS. 5 to 7 are simplified diagrams that combine a
plurality of cross sections passing through the optical axis AX. In
FIG. 25 the lens barrel 20 is shown in its refracted state, in FIG.
26 the lens barrel 20 is shown in its wide angle state, and in FIG.
27 the lens barrel 20 is shown in its telephoto state. In this
embodiment, the "imaging enabled state" of the digital camera 1
means a state from the wide angle state to the telephoto state of
the lens barrel 20.
[0213] A gear portion 212 of the first rotary frame 210 meshes with
the zoom gear 242 (not shown). The cam follower B1 of the first
rotary frame 210 is engaged with the cam groove b1 of the
stationary frame 100. Therefore, the first rotary frame 210 moves
in the optical axis direction while rotating in the peripheral
direction under the drive force of the zoom motor 241.
[0214] The rectilinear protrusion A1 of the first rectilinear frame
110 is engaged with the rectilinear groove a1 of the stationary
frame 100. The bayonet protrusion E1 of the first rotary frame 210
is engaged with the bayonet groove e1 of the first rectilinear
frame 110. Therefore, the first rectilinear frame 110 is movable
rectilinearly in the optical axis direction along with the first
rotary frame 210.
[0215] A rectilinear cam follower AB2 of the second rectilinear
frame 120 is inserted into the cam groove b2 of the first rotary
frame 210, and is engaged with the rectilinear groove a2 of the
first rectilinear frame 110. Therefore, the second rectilinear
frame 120 moves rectilinearly in the optical axis direction
according to the rotation of the first rotary frame 210.
[0216] A rectilinear protrusion A3 of the second rotary frame 220
is engaged with a rectilinear groove a3 of the first rotary frame
210. The bayonet protrusion E2 of the second rotary frame 220 is
engaged with the bayonet groove e2 of the second rectilinear frame
120. Therefore, the second rotary frame 220 moves in the optical
axis direction along with the second rectilinear frame 120 while
rotating in the peripheral direction along with the first rotary
frame 210.
[0217] A latching portion 122 of the second rectilinear frame 120
is latched in a latching recess 133 of the third rectilinear frame
130. The bayonet protrusion E3 of the third rectilinear frame 130
is engaged with the bayonet groove e3 of the second rotary frame
220. At least two of the three rectilinear protrusions A3 of the
second rotary frame 220 are disposed at least about 120.degree.
apart, the two latching portions 122 of the second rectilinear
frame 120 are also disposed at least about 120.degree. apart, and
the relative rotation angle during zoom drive is set to about
120.degree. or less. Therefore, the third rectilinear frame 130
moves rectilinearly in the optical axis direction along with the
second rectilinear frame 120 without interfering with the rotation
of the second rotary frame 220.
[0218] Also, at least two of the three rectilinear protrusions A3
of the second rotary frame 220 are spaced apart by about
150.degree., the spacing of the two latching portions 122 of the
second rectilinear frame 120 is also about 150.degree., and the
relative rotation angle during zoom drive is set to about
150.degree. or less. Therefore, the third rectilinear frame 130
does not interfere with the rotation of the second rotary frame
220. The same applies to other angles.
[0219] The rectilinear protrusion A4 of the first cosmetic frame
310 is engaged with the rectilinear groove a4 of the second
rectilinear frame 120. The cam protrusion B3 of the first cosmetic
frame 310 is engaged with the cam groove b3 of the second rotary
frame 220. Therefore, the first cosmetic frame 310 can move
rectilinearly in the optical axis direction according to the
rotation of the second rotary frame 220.
[0220] A rectilinear protrusion A5 of the second cosmetic frame 320
is engaged with a rectilinear groove a5 of the third rectilinear
frame 130. The cam protrusion B4 of the second cosmetic frame 320
is engaged with the cam groove b4 of the second rotary frame 220.
Therefore, the second cosmetic frame 320 can move rectilinearly in
the optical axis direction according to the rotation of the second
rotary frame 220.
[0221] A rectilinear protrusion A6 of the shutter frame 335 is
engaged with a rectilinear groove a6 of the third rectilinear frame
130. The cam protrusion B5 of the shutter frame 335 is engaged with
the cam groove b5 of the second rotary frame 220. Therefore, the
shutter frame 335 can move rectilinearly in the optical axis
direction according to the rotation of the second rotary frame
220.
[0222] The third lens group frame 330 is mounted to the shutter
frame 335, and when the shutter frame 335 moves rectilinearly in
the optical axis direction with respect to the third rectilinear
frame 130, the retracting lens frame 401 of the third lens group
frame 330 is rotated by a refracting mechanism (a guide groove a7
of the third rectilinear frame 130 and a driven portion 411 of the
retracting lens frame 401). Consequently, the refracting lens frame
401 moves from the refracted position to the correction enabled
position during the transition period between the imaging enabled
state and the housed state. Also, during the transition period
between the imaging enabled state and the housed state, the
retracting lens frame 401 moves from the correction enabled
position to the refracted position. When the retracting lens frame
401 is disposed in the correction enabled position, the third lens
group L3 is movable within a plane that is perpendicular to the
optical axis. Specifically, image blur correction is possible in
this state.
[0223] As discussed above, the rotation of the first rotary frame
210 and the second rotary frame 220 produced by the drive force of
the zoom motor 241 results in rectilinear movement of the first to
third rectilinear frames 110 to 130 and the lens group frames 310,
320, and 335.
Configuration of Retracting Mechanism
[0224] The configuration of the retracting mechanism of the lens
barrel 20 will now be described through reference to the
drawings.
6. Configuration of Third Rectilinear Frame 130
[0225] FIGS. 28 and 29 are oblique views of the third rectilinear
frame 130.
[0226] The third rectilinear frame 130 has a third rectilinear
frame main body 131, a flange 132, and two latching recesses
133.
[0227] The third rectilinear frame main body 131 is in the form of
a cylinder, and has an inner peripheral face 130S and an outer
peripheral face 130T.
[0228] The flange 132 is formed in an annular shape and is provided
to the rear end part of the outer peripheral face 130T.
[0229] The two latching recesses 133 are cut-outs formed in the
outer edge of the flange 132. The two latching portions 122 of the
second rectilinear frame 120 are latched in the two latching
recesses 133 of the third rectilinear frame 130, which prevents
relative rotation of the third rectilinear frame 130 with respect
to the second rectilinear frame 120.
[0230] The third rectilinear frame 130 has two pairs of bayonet
protrusions E3, three rectilinear grooves a5, and three rectilinear
grooves a6. In FIG. 28, however, only a pair of the bayonet
protrusions E3 is shown. A pair of the bayonet protrusions E3
includes two bayonet protrusions E3.
[0231] The two bayonet protrusions E3 are formed in the approximate
center of the outer peripheral face 130T along the peripheral
direction. The two bayonet protrusions E3 are engaged with the two
bayonet grooves e3 of the second rotary frame 220. In this
embodiment, the bayonet protrusions E3 and the bayonet grooves e3
constitute a bayonet mechanism for rotatably engaging the third
rectilinear frame 130 with the second rotary frame 220.
[0232] The three rectilinear grooves a5 pass through the third
rectilinear frame main body 131 from the inner peripheral face 130S
to the outer peripheral face 130T.
[0233] The three rectilinear grooves a6 pass through the third
rectilinear frame main body 131 from the inner peripheral face 130S
to the outer peripheral face 130T.
[0234] In this embodiment, the three rectilinear grooves a5 and the
three rectilinear grooves a6 are disposed alternately in the
peripheral direction.
[0235] As shown in FIG. 28, the third rectilinear frame 130 further
has the guide groove a7 formed in the inner peripheral face of the
third rectilinear frame main body 131, and a reinforcing portion
130H (shaded part) formed near the guide groove a7.
[0236] The guide groove a7 guides the driven portion 411 (discussed
below) as a cam follower. The guide groove a7 and the driven
portion 411 constitute a cam mechanism for moving the retracting
lens frame 401. This cam mechanism varies the orientation of the
retracting lens frame 401 by moving the third rectilinear frame 130
relatively in the optical axis direction with respect to the
refracting lens frame 401.
[0237] As shown in FIG. 28, the guide groove a7 has a portion that
is inclined to the optical axis (sloped part), and a portion that
is parallel to the optical axis (parallel part). When the driven
portion 411 is guided by this sloped part, the retracting lens
frame 401 rotates around the refraction shaft 501b. The refracting
lens frame 401 transitions between an image blur correction enabled
position and a retracted position by rotating about the refraction
shaft 501b.
[0238] The refracting lens frame 401 is biased by the rotary spring
403 around the refraction shaft 501.
[0239] Therefore, when the retracting lens frame 401 is rotated
against the biasing force of the rotary spring 403 by the guide
groove a7 and the driven portion 411, the driven portion 411 comes
into contact with one side (the side face on one side) of the guide
groove a7. Therefore, the refracting lens frame 401 is rotated as
long as there is a side face on the rear side in the optical axis
direction.
[0240] When the guide groove a7 that engages with the driven
portion 411 is formed in the third rectilinear frame 130, the
rotation of the refracting lens frame 401 is started earlier during
the transition period between the imaging enabled state and the
housed state.
[0241] Also, the rotational accuracy of the retracting lens frame
401 can be improved by forming the guide groove a7 that engages
with the driven portion 411 in the third rectilinear frame 130.
[0242] Furthermore, centering during refraction can be performed
more accurately by forming the guide groove a7 that engages with
the driven portion 411 in the third rectilinear frame 130. When the
guide groove a7 is constituted by the third rectilinear frame 130,
a centering mechanism for the OIS frame 400 is also formed in the
third rectilinear frame 130. Therefore, the positional accuracy of
the refracting lens frame 401 and the OIS frame 400 can be
improved.
[0243] The reinforcing portion 130H is formed partially in the
third rectilinear frame main body 131. The reinforcing portion 130H
is formed in the inner peripheral face of the third rectilinear
frame main body 131. More specifically, the reinforcing portion
130H is formed in the third rectilinear frame main body 131 so as
to protrude toward the inside of the third rectilinear frame main
body 131. Specifically, using the outer peripheral face of the
third rectilinear frame main body 131 as a reference, the
reinforcing portion 130H is formed so that its thickness increases
toward the inner peripheral side as compared to the other portions.
Also, the reinforcing portion 130H is formed near the guide groove
a7, such as adjacent to the guide groove a7.
[0244] The thickness of the reinforcing portion 130H is determined
by the depth of the guide groove a7. Specifically, the thickness of
the reinforcing portion 130H is set so that the depth of the guide
groove a7 (the radial direction dimension of the guide groove a7)
fits in the reinforcing portion 130H. Also, the depth of the guide
groove a7 is determined by the size (height) of the driven portion
411 inserted into the guide groove a7. The depth of the guide
groove a7 (the radial direction dimension of the guide groove a7)
is set so as to accommodate the height of the driven portion 411
(the radial direction dimension of the driven portion 411).
[0245] The third rectilinear frame main body 131 is preferably as
thin as possible in order to reduce the outside diameter of the
lens barrel 20. However, since the cam mechanism that moves the
retracting lens frame 401 (that is, the portion where the guide
groove a7 and the driven portion 411 engage) needs to be strong, a
certain amount of thickness is necessary. If the portion having
this certain amount of thickness is formed on the inner peripheral
face side of the third rectilinear frame main body 131, this
minimizes the increase in the outside diameter of the third
rectilinear frame main body 131. Specifically, an increase in the
outside diameter of the lens barrel 20 can be minimized.
[0246] As shown in FIG. 29, the third rectilinear frame 130 has
three shunting grooves a9 for restricting the movement of the OIS
frame 400 with respect to the third rectilinear frame 130 or the
shutter frame 335. The three shunting grooves a9 are formed in the
inner peripheral face 130S of the third rectilinear frame main body
131. The three shunting grooves a9 are formed in the third
rectilinear frame main body 131 spaced apart by a specific distance
in the peripheral direction in the inner peripheral face 1305.
[0247] The three shunting grooves a9 are grooves extending in the
optical axis direction. The shunting grooves a9 are formed so that
the groove is larger on the flange 132 side. More specifically, the
shunting grooves a9 have a first groove a91, a second groove a92,
and a third groove a93. The first groove a91 and the second groove
a92 are such that the shape of a cross section perpendicular to the
optical axis is semicircular, semi-elliptical, trapezoidal,
rectangular, parabolic, or a combination of these shapes.
[0248] The first grooves a91 are grooves formed on the flange 132
side. The width and depth of the first grooves a91 are greater than
the width and depth of the second grooves a92. The shape of the
third grooves a93 is a sloped face, a conical face, a curved face,
or a combination of these shapes, so that there is a smooth
transition from the width and depth of the first grooves a91 to the
width and depth of the second grooves a92. If shunting protrusions
404 (see FIG. 32) of the OIS frame 400 (discussed below) are
disposed in the first grooves a91, the shunting protrusions 404 is
movable inside the first grooves a91. Specifically, in this case,
the OIS frame 400 can move within a plane that is perpendicular to
the optical axis with respect to the third rectilinear frame 130 or
the shutter frame 335.
[0249] The second grooves a92 are grooves that extend in the
optical axis direction from the first grooves a91. If the shunting
protrusions 404 (see FIG. 32) of the OIS frame 400 (discussed
below) are disposed in the second grooves a92, the OIS frame 400 is
restrained in the radial direction and the peripheral direction
with respect to the third rectilinear frame 130 or the shutter
frame 335. Consequently, movement of the OIS frame 400 is
restricted with respect to the third rectilinear frame 130 or the
shutter frame 335.
[0250] The third grooves a93 are grooves that extend in the optical
axis direction and link the first grooves a91 and the second
grooves a92. If the shunting protrusions 404 (see FIG. 32) of the
OIS frame 400 (discussed below) are disposed in the third grooves
a93, the OIS frame 400 gradually transitions from a state of being
movable within a plane that is perpendicular to the optical axis to
a state in which it is restricted in the radial direction and the
peripheral direction, with respect to the third rectilinear frame
130 or the shutter frame 335.
[0251] Specifically, when the shunting protrusions 404 of the OIS
frame 400 are disposed from the first grooves a91, via the third
grooves a93, to the second grooves a92, this centers the OIS frame
400.
[0252] A mechanism for centering the OIS frame 400 (centering
mechanism) is constituted by the shunting grooves a9 (a91, a92, and
a93) and the shunting protrusions 404 of the OIS frame 400.
7. Configuration of Third Lens Group Frame 330
[0253] FIG. 30 shows a state in which the third lens group frame
330 is housed in the interior of the shutter frame 335. The
configuration of the third lens group frame 330 will be described
through reference to FIG. 30.
[0254] The third lens group frame 330 (that is, an OIS (optical
image stabilizer) unit) mainly has the OIS frame 400, the
retracting lens frame 401, the thrust spring 402, the rotary spring
403, and the third lens group L3 used for image blur
correction.
[0255] As shown in FIG. 30, the OIS frame 400 is mounted to the
shutter frame 335. The optical axis direction layout of the OIS
frame 400 with respect to the shutter frame 335 is such that three
OIS shafts press-fitted to the shutter frame 335 are supported by
being clamped in the optical axis direction by optical axis
direction supports of the OIS frame 400 at three places. The
directional position of the OIS frame 400 perpendicular to the
optical axis with respect to the shutter frame 335 is such that one
OIS rotary shaft press-fitted to the shutter frame 335 is clamped
in the optical axis direction by a perpendicular direction support
of the OIS frame 400 at one place, and an optical axis direction
stopper pin is supported by coming into contact with the peripheral
wall of a movement range restrictor 338 of the OIS frame 400.
[0256] As shown in FIGS. 31 and 32, the OIS frame 400 has a main
body portion 405, a first linking portion 407, and a second linking
portion 408. The main body portion 405 has a hole 405a and a first
cut-out 405b.
[0257] In a state in which the OIS frame 400 is mounted to the
shutter frame 335, the first linking portion 407 is disposed above
magnets 521 and coils 522 (actuators; discussed below).
[0258] The OIS frame 400 is movable within a plane that is
perpendicular to the optical axis. More specifically, the magnets
521 are fixed to the OIS frame 400, and the coils 522 are fixed to
the shutter frame 335 at a position opposite the magnets 521. In
this state, when power is supplied from a camera circuit (not
shown) to the coils 522 of the shutter frame 335, current flows and
a magnetic field is generated in the coils 522. This magnetic field
drives the magnets 521 of the OIS frame 400, and this drive force
causes the OIS frame 400 to move in a plane that is perpendicular
to the optical axis.
[0259] As shown in FIG. 32, the OIS frame 400 has the shunting
protrusions 404 that engage with the shunting grooves a9 of the
third rectilinear frame 130. The shunting protrusions 404 are
formed integrally with the main body portion 405 of the OIS frame
400. More specifically, the two shunting protrusions 404 are formed
on the main body portion 405 so as to protrude outward from the
outer peripheral part of the main body portion. Also, the two
shunting protrusions 404 are formed integrally with the main body
portion 405 and spaced apart by a specific distance around the
outer peripheral part of the main body portion 405. The two
shunting protrusions 404 are respectively fitted into and guided by
the two shunting grooves a9 of the third rectilinear frame 130.
[0260] More specifically, in a state in which the OIS frame 400 is
mounted to the shutter frame 335, when the OIS frame 400 approaches
the third rectilinear frame 130, the shunting protrusions 404
formed on the OIS frame 400 are introduced from the flange 132 side
of the third rectilinear frame 130 into the first grooves a91 of
the third rectilinear frame 130. In a state in which the shunting
protrusions 404 are disposed in the first grooves a91, the OIS
frame 400 is movable in a plane that is perpendicular to the third
rectilinear frame 130 or the shutter frame 335.
[0261] Then, in a state in which the OIS frame 400 is mounted to
the shutter frame 335, if the OIS frame 400 moves further in the
optical axis direction on the inner peripheral side of the third
rectilinear frame 130, the shunting protrusions 404 are introduced
into the third grooves a93. Then, the OIS frame 400 gradually
transitions from a state of being movable in a plane that is
perpendicular to the optical axis to a state of being restricted in
the radial direction and the peripheral direction with respect to
the third rectilinear frame 130 or the shutter frame 335.
[0262] Then, when the shunting protrusions 404 are introduced into
the second grooves a92, the shunting protrusions 404 are pressed by
the second grooves a92 away from the inner peripheral face 1305 of
the third rectilinear frame 130. This restricts the movement of the
OIS frame 400 with respect to the third rectilinear frame 130 or
the shutter frame 335. The result is that the OIS frame 400 is
centered.
[0263] Here, when the shunting protrusions 404 are guided by the
shunting grooves a9 of the third rectilinear frame 130, the third
rectilinear frame 130 is positioned away from the shunting grooves
a9. The refraction operation of the refracting lens frame 401 is
started in this state. That is, the driven portion 411 of the
retracting lens frame 401 is guided by the guide groove a7 of the
third rectilinear frame 130. The drive force received by the driven
portion 411 of the refracting lens frame 401 from the guide groove
a7 then acts in the direction in which the shunting protrusions 404
are pushed into the shunting grooves a9. This reliably reduces
looseness between the shunting protrusions 404 and the shunting
grooves a9. That is, the center of the OIS frame 400 can be
performed more reliably.
[0264] The center of the OIS frame 400 in this example was executed
before starting the refraction of the retracting lens frame 401,
but what is important is that the centering be completed by the
time the refraction operation is complete.
[0265] As shown in FIG. 31, the refracting lens frame 401 is
supported by the OIS frame 400 so as to be movable around the
retraction shaft 501b, which is substantially parallel to the
optical axis. The retracting lens frame 401 supports the third lens
group L3 used for image blur correction, with a third lens support
420. The third lens group L3 is made up of at least one lens. The
term "refraction shaft" as used below will sometimes be used in the
sense of "the axis of the refraction shaft."
[0266] As shown in FIG. 31, the refracting lens frame 401 has a
main body portion 401a, a bearing 410, the driven portion 411, a
positioning portion 412, the third lens support 420, and an
engagement portion (not shown). The bearing 410 is formed
integrally with the main body portion 401a.
[0267] As shown in FIGS. 31 and 32, the bearing 410 is rotatably
mounted to the support shaft 501b (refraction shaft) provided to
the OIS frame 400. A hole into which the refraction shaft 501b is
inserted is formed in the bearing 410.
[0268] The driven portion 411 is the portion that is driven against
the biasing force of the rotary spring 403 (discussed below) during
the transition period between the imaging enabled state and the
housed state. The driven portion 411 is formed integrally
protruding outward from the main body portion 401a. The driven
portion 411 is engaged with the guide groove a7 formed in the inner
peripheral face of the third rectilinear frame 130. More precisely,
the driven portion 411 is engaged with the guide groove a7 of the
third rectilinear frame 130 via an opening (not shown) in the
shutter frame 335. The driven portion 411 is guided by the guide
groove a7 of the third rectilinear frame 130 when the third
rectilinear frame 130 moves relatively in the optical axis
direction with respect to the retracting lens frame 401.
Consequently, the orientation of the retracting lens frame 401
changes during the transition period between the imaging enabled
state and the housed state.
8. Configuration of Shutter Frame 335
[0269] The configuration of the shutter frame 335 will now be
described through reference to FIGS. 30 and 31.
[0270] As shown in FIG. 30, the shutter frame 335 has a shutter
frame main body 336, three rectilinear protrusions A6, and three
cam protrusions B5. As shown in FIG. 31, the shutter frame 335 also
has an opening 356, a light blocking portion 357, and a first
restrictor 337a.
[0271] The shutter frame main body 336 is in the form of a
cylinder, and has an outer peripheral face 335T.
[0272] The three rectilinear protrusions A6 are formed on the outer
peripheral face 335T, and are disposed at a substantially constant
pitch in the peripheral direction. The three rectilinear
protrusions A6 are engaged with the three rectilinear grooves a6 of
the third rectilinear frame 130.
[0273] The three cam followers B5 are provided to the front end of
the three rectilinear protrusions A6. The three cam followers B5
are engaged with the three cam grooves b5 of the second rotary
frame 220.
[0274] The opening 356 is the portion that houses a part 420b of
the third lens support 420 during the transition period between the
imaging enabled state and the housed state. As shown in FIG. 30,
the part 420b of the third lens support 420 is the portion adjacent
to a second cut-out 420a during the transition period between the
imaging enabled state and the housed state. More precisely, the
light blocking portion 357 is provided to the opening 356 in order
to block light rays.
9. Action and Effect
[0275] (1) With this lens barrel 20, the third rectilinear frame
130 restricts the in-plane movement of the OIS frame 400 during the
transition period between the imaging enabled state and the housed
state. Consequently, in the housed state, there is no need to
provide clearance or the like for avoiding contact with members
caused by in-plane movement of the OIS frame 400, so the lens
barrel 20 can be more compact.
[0276] (2) With this lens barrel 20, when the shunting grooves a9
of the third rectilinear frame 130 are engaged with the shunting
protrusions 404 of the OIS frame 400, in-plane movement of the OIS
frame 400 is restricted by the third rectilinear frame 130 during
the transition period between the imaging enabled state and the
housed state. Consequently, there is no need to provide the
above-mentioned clearance, etc., so the lens barrel can be more
compact.
[0277] (3) With this lens barrel 20, the third rectilinear frame
130 restricts the in-plane movement of the OIS frame 400 and
refracts the refracting lens frame 401. Specifically, restriction
of the in-plane movement of the OIS frame 400 and retraction of the
refracting lens frame 401 can be accomplished with just one member
(the third rectilinear frame 130), so this improves accuracy during
in-plane restriction of the OIS frame 400 and accuracy during
refraction of the retracting lens frame 401.
Other Embodiments
[0278] (A) In the above embodiments the lens barrel 20 comprised
the third rectilinear frame 130, but need not comprise the third
rectilinear frame 130.
[0279] (B) In the above embodiments, the second rectilinear frame
120 was disposed on the inside of the first rotary frame 210, but
this is not the only option. The second rectilinear frame 120 may
instead be disposed on the outside of the first rotary frame 210.
Specifically, the second rectilinear frame 120 should be disposed
on the inside of the first rectilinear frame 110.
[0280] (C) In the above embodiments, the lens barrel 20 comprised
the first to fifth lens groups L1 to L5, but this is not the only
option. The lens barrel 20 should comprise at least the first lens
group L1.
[0281] (D) In the above embodiments, the lens barrel 20 comprised a
three-stage telescoping zoom mechanism, but this is not the only
option. The lens barrel 20 may have a telescoping mechanism of more
than three stages.
[0282] (E) In the above embodiments, the cam grooves b were formed
in one of two frames, and the cam protrusions B were formed in the
other frame, but this is not the only option. The frames on which
the cam protrusions B and the cam grooves b are formed may be
switched around. Also, the cam grooves b and the cam protrusions B
may both be formed in each of the two frames.
[0283] (F) In the above embodiments, the rectilinear grooves a were
formed in one of two frames, and the rectilinear protrusions A were
formed in the other frame, but this is not the only option. The
frames on which the rectilinear protrusions A and the rectilinear
grooves a are formed may be switched around. Also, the rectilinear
grooves a and the rectilinear protrusions A may both be formed in
each of the two frames.
[0284] (G) In the above embodiments, the bayonet grooves e were
formed in one of two frames, and the bayonet protrusions E were
formed in the other frame, but this is not the only option. The
frames on which the bayonet protrusions E and the bayonet grooves e
are formed may be switched around. Also, the bayonet grooves e and
the bayonet protrusions E may both be formed in each of the two
frames.
[0285] (H) In the above embodiments, the third lens group L3
retracted to the outside in the radial direction of the fourth and
fifth lens groups L4 and L5, but this is not the only option. The
third lens group L3 may be disposed in front of the fourth and
fifth lens groups L4 and L5 in the refracted state.
[0286] (I) In the above embodiments, an example was given in which
the refraction shaft portion 501 (retraction shaft 501b) was
provided to the OIS frame 400, and the shaft support 601 was
provided to the retracting lens frame 401, but the shaft support
601 may be provided to the OIS frame 400, and the refraction shaft
portion 501 (refraction shaft 501b) may be provided to the
refracting lens frame 401.
[0287] (J) In the above embodiments, as shown in FIG. 12, an
example was given in which the anti-rotation portion 502 of the OIS
frame 400 was formed in a concave shape, and the third contact
portion 603C of the refracting lens frame 401 come into contact
with the sloped face 502a of the anti-rotation portion 502.
Instead, as shown in FIG. 33, the third contact portion 603C of the
refracting lens frame 401 may come into contact with two side faces
512a of a concave portion 512 of an anti-rotation portion 502'. In
this case, the two side faces 512a of the concave portion 512 are
sloped and opposite each other. More specifically, the two side
faces 512a of the concave portion 512 are formed so as to approach
each other toward the bottom 512b of the concave portion 512. This
allows the refracting lens frame 401 to be positioned more reliably
with respect to the OIS frame 400.
[0288] (K) In the above embodiments, an example was given in which
the in-plane movement of the OIS frame 400 was restricted and the
refracting lens frame 401 was retracted with just one member (the
master flange 105 in the first embodiment, and the third
rectilinear frame 130 in the second embodiment). Instead, the
restriction of the in-plane movement of the OIS frame 400 and the
refraction of the refracting lens frame 401 may be accomplished
with a plurality of members.
Third Embodiment
[0289] It is an object of Embodiment 3 to increase shatter
strength.
[0290] The lens barrel comprises a frame body, a support frame, and
a refracting lens frame. The support frame is supported by the
frame body and is movable within a plane that is perpendicular to
the optical axis, with respect to the frame body. The refracting
lens frame is supported by the support frame, and moves around a
retraction shaft that is substantially parallel to the optical axis
during the transition period between the imaging enabled state and
the housed state. The frame body has a main body portion and a
first restrictor that is provided a specific distance away from the
main body portion. The retracting lens frame has a first engagement
portion that engages with the first restrictor. Movement of the
refracting lens frame in the optical axis direction is restricted
by disposing this first engagement portion between the main body
portion and the restrictor.
[0291] The technology disclosed herein provides a lens barrel with
which the refracting lens frame can operate stably.
Configuration of Digital Camera 1
[0292] The configuration of the digital camera 1 will now be
described through reference to the drawings. FIG. 34 is an oblique
view of the digital camera 1. FIG. 35 is an oblique view of the
lens barrel 20.
[0293] As shown in FIG. 34, the digital camera 1 comprises the
housing 10 and the lens barrel 20.
[0294] The housing 10 is made up of the front panel 11, the rear
panel 12, and the side panel 13. The opening 10S is formed in the
front panel 11.
[0295] The lens barrel 20 comprises a three-stage retractable zoom
mechanism. The lens barrel 20 is housed in the housing 10 when not
being used for imaging, and is deployed forward from the opening
10S during imaging. More specifically, as shown in FIG. 35, the
lens barrel 20 has the first movable lens barrel portion 21, the
second movable lens barrel part 22, the third movable lens barrel
part 23, and the stationary lens barrel 24.
[0296] The first movable lens barrel part 21 is configured to
deploy with respect to the stationary lens barrel part 24. The
second movable lens barrel part 22 is configured to deploy with
respect to the first movable lens barrel part 21. The third movable
lens barrel part 23 is configured to deploy with respect to the
second movable lens barrel part 22. The stationary lens barrel part
24 is fixed inside the housing 10. When the lens barrel 20 is
deployed, the third movable lens barrel part 23 is positioned the
farthest forward out of the first to third movable lens barrel
parts 21 to 23.
Detailed Configuration of Lens Barrel 20
[0297] Next, the detailed configuration of the lens barrel 20 will
be described through reference to the drawings. FIG. 36 is an
exploded oblique view of the lens barrel 20.
[0298] The first to third movable lens barrel parts 21 to 23 of the
lens barrel 20 are deployed from the stationary lens barrel part 24
along the optical axis AX of the optical system. The optical system
includes first to fourth lens groups L1 to L4. In the following
description, a direction parallel to the optical axis AX will be
called the "optical axis direction," a direction perpendicular to
the optical axis direction will be called the "radial direction,"
and a direction that follows a circle whose center is the optical
axis AX will be called the "peripheral direction."The optical axis
AX substantially coincides with the axis of the various frames that
make up the lens barrel 20.
1. First Movable Lens Barrel Part 21
[0299] The first movable lens barrel part 21 has the first
rectilinear frame 110, the first rotary frame 210, and the first
cosmetic frame 301. The first rectilinear frame 110 is a
cylindrical plastic member disposed on the inside in the radial
direction of the stationary frame 100 (discussed below). The first
rotary frame 210 is a cylindrical plastic member disposed on the
inside in the radial direction of the stationary frame 100. The
first cosmetic frame 301 is a cylindrical sheet metal member that
covers the outer periphery of the first rectilinear frame 110.
2. Second Movable Lens Barrel Part 22
[0300] The second movable lens barrel part 22 has the second
rectilinear frame 120, the second rotary frame 220, the third
rectilinear frame 130, the second lens group frame 320, the second
lens group L2, the third lens group frame 330, the third lens group
L3, the shutter frame 335, and the second cosmetic frame 302.
[0301] The second rectilinear frame 120 is a cylindrical plastic
member disposed on the inside in the radial direction of the first
rotary frame 210. The second rotary frame 220 is a cylindrical
plastic member disposed on the inside in the radial direction of
the second rectilinear frame 120.
[0302] The third rectilinear frame 130 is a cylindrical plastic
member disposed on the inside in the radial direction of the second
rotary frame 220. The second lens group frame 320 is disposed on
the inside in the radial direction of the third rectilinear frame
130, and supports the second lens group L2. The third lens group
frame 330 is housed in the shutter frame 335, and supports the
third lens group L3 used for image blur correction. The third lens
group frame 330 is supported pivotably in the radial direction by
the shutter frame 335, and constitutes an image blur correction
mechanism along with the third lens group L3.
[0303] The shutter frame 335 is disposed on the inside in the
radial direction of the third rectilinear frame 130, and has a
built-in shutter mechanism. The shutter frame 335 supports the
third lens group frame 330 pivotably in the radial direction. A
control-use flexible wire 335a is connected to the shutter frame
335.
[0304] The control-use flexible wire 335a is disposed along the
inner peripheral face of the stationary frame 100, and is connected
to a control device (not shown). The control-use flexible wire 335a
transmits control signals to the shutter mechanism and the image
blur correction mechanism (discussed below). The second cosmetic
frame 302 is a cylindrical sheet metal member that covers the outer
periphery of the second rectilinear frame 120.
3. Third Movable Lens Barrel Part 23
[0305] The third movable lens barrel part 23 has the first lens
group frame 310, the first lens group L1, and the third cosmetic
frame 303.
[0306] The first lens group frame 310 is disposed between the
second rectilinear frame 120 and the second rotary frame 220. The
first lens group frame 310 supports the first lens group L1, which
is used to bring light into the lens barrel 20. The third cosmetic
frame 303 is a cylindrical sheet metal member that covers the outer
periphery of the first lens group frame 310.
4. Stationary Lens Barrel Part 24
[0307] The stationary lens barrel part 24 has the stationary frame
100, the fourth lens group frame 340, the fourth lens group L4, the
zoom motor zoom motor 241, the zoom gear 242, the focus motor 243,
the master flange 244, the imaging element 245, and the imaging
element flexible wire 245a.
[0308] The stationary frame 100 is a cylindrical plastic member
disposed on the outside in the radial direction of the first rotary
frame 210 and the first rectilinear frame 110. The fourth lens
group frame 340 is attached to the master flange 244, and is driven
in the optical axis direction by the focus motor 243. The fourth
lens group frame 340 supports the fourth lens group L4, which is
used for focal adjustment.
[0309] The zoom motor 241 is a drive source that is used to deploy
the first to third movable lens barrel parts 21 to 23, and is
attached to the side face of the stationary frame 100. The zoom
gear 242 transmits the drive force of the zoom motor 241 to the
first rotary frame 210. The front end of the zoom gear 242 is
supported by the stationary frame 100, and the rear end of the zoom
gear 242 is supported by the master flange 244. The focus motor 243
is a drive source that is used to drive the fourth lens group frame
340 in the optical axis direction, and is attached to the master
flange 244. The master flange 244 is a flat plastic member that
covers the rear of the stationary frame 100. The imaging element
245 is fitted into the center of the master flange 244. The imaging
element flexible wire 245a is affixed to the rear face of the
master flange 244. The imaging element flexible wire 245a is
connected to a control device (not shown), and transmits signals
from the imaging element 245.
Configuration of Frames
[0310] The frames that make up the lens barrel 20 will now be
described through reference to the drawings. More specifically, the
configurations of the stationary frame 100, the first rectilinear
frame 110, the first rotary frame 210, the second rectilinear frame
120, the second rotary frame 220, the third rectilinear frame 130,
the first lens group frame 310, the second lens group frame 320,
the third lens group frame 330, and the shutter frame 335 will be
described in order, after which we will describe how the frames are
engaged with each other.
1. Configuration of Stationary Frame 100
[0311] FIG. 37 is an oblique view of the stationary frame 100. The
stationary frame 100 has the stationary frame main body 101 and the
zoom gear support 102.
[0312] The stationary frame main body 101 is formed in a
cylindrical shape, and has an inner peripheral face 100S and an
outer peripheral face 100T.
[0313] The support 102 is provided so as to protrude from the outer
peripheral face 100T. The support 102 rotatably supports the front
end of the zoom gear 242. In this embodiment, the support 102 is
covered by the front panel 11, so it is not exposed on the outside
of the housing 10 (see FIG. 34). The teeth of the zoom gear 242
protrude on the inside of the stationary frame main body 101.
[0314] The stationary frame 100 has five rectilinear grooves a1 and
three cam grooves b1. In FIG. 37, however, only three rectilinear
grooves a1 and two cam grooves b1 are shown.
[0315] The five rectilinear grooves a1 are formed in the inner
peripheral face 100S in the optical axis direction, and are
suitably spaced apart in the peripheral direction.
[0316] The three cam grooves b1 are formed in the inner peripheral
face 100S so as to intersect the optical axis direction.
2. Configuration of First Rectilinear Frame 110
[0317] FIG. 38 is an oblique view of the first rectilinear frame
110. The first rectilinear frame 110 has a first rectilinear frame
main body 111, five rectilinear protrusions A1, three rectilinear
grooves a2, a bayonet groove e1, and a bayonet protrusion E0.
[0318] The rectilinear frame main body 111 is formed in a
cylindrical shape, and has an inner peripheral face 110S and an
outer peripheral face 110T.
[0319] The five rectilinear protrusions A1 are provided at the rear
end of the outer peripheral face 110T. The five rectilinear
protrusions A1 are engaged with the five rectilinear grooves a1 of
the stationary frame 100.
[0320] The three rectilinear grooves a2 are formed in the inner
peripheral face 110S in the optical axis direction.
[0321] The bayonet groove e1 is formed in an arc shape in the
peripheral direction at the rear end of the inner peripheral face
110S. The bayonet groove e1 intersects the three rectilinear
grooves a2.
[0322] The bayonet protrusion E0 is disposed at the front end of
the inner peripheral face 110S. The bayonet protrusion E0 is formed
in an arc shape in the peripheral direction. In this embodiment, a
plurality of bayonet protrusions E0 are provided in the peripheral
direction.
3. Configuration of First Rotary Frame 210
[0323] FIG. 39 is an oblique view of the first rotary frame 210.
The first rotary frame 210 has a first rotary frame main body 211
and the gear portion 212. The first rotary frame main body 211 is
formed in a cylindrical shape, and has an inner peripheral face
210S and an outer peripheral face 210T.
[0324] The gear portion 212 is provided to the rear end of the
outer peripheral face 210T, and is formed in the peripheral
direction. When the gear portion 212 meshes with the zoom gear 242,
the first rotary frame 210 is rotated in the peripheral direction
by the drive force of the zoom motor 241. Although not depicted,
the gear portion 212 is located further to the rear than the
rectilinear protrusions A1 of the first rectilinear frame 110.
[0325] The first rotary frame 210 has three cam followers B1, three
bayonet protrusions E1, three cam grooves b2, a bayonet groove e0,
and three rectilinear grooves a3. In FIG. 39, however, only one of
the rectilinear grooves a3 is shown.
[0326] The three cam followers B1 are provided to the rear end of
the outer peripheral face 210T. Two of the three cam followers B1
are disposed at the two ends of the gear portion 212. The three cam
followers B1 are engaged with the three cam grooves b1 of the
stationary frame 100.
[0327] The bayonet protrusions E1 are formed in the peripheral
direction at the rear end of the outer peripheral face 210T. The
bayonet protrusions E1 are disposed in front of the gear portion
212. The bayonet protrusions E1 are engaged with the bayonet groove
e1 of the first rectilinear frame 110. In this embodiment, the
bayonet protrusions E1 and the bayonet groove e1 constitute a
bayonet mechanism for rotatably engaging the first rotary frame 210
in the first rectilinear frame 110.
[0328] The three cam grooves b2 pass through the first rotary frame
main body 211 from the inner peripheral face 210S to the outer
peripheral face 210T.
[0329] The bayonet groove e0 is formed at the front end of the
outer peripheral face 210T. The bayonet groove e0 is formed in an
arc shape in the peripheral direction. The bayonet groove e0
intersects the three cam grooves b2. The bayonet protrusions E0 are
engaged with the bayonet groove e0.
[0330] The three rectilinear grooves a3 are formed in the inner
peripheral face 210S in the optical axis direction. Two of the
three rectilinear grooves a3 are close together, and are formed
from 120.degree. to 180.degree. away from the other one.
4. Configuration of Second Rectilinear Frame 120
[0331] FIG. 40 is an oblique view of the second rectilinear frame
120. The second rectilinear frame 120 has a second rectilinear
frame main body 121 and two latching portions 122.
[0332] The second rectilinear frame main body 121 is formed in a
cylindrical shape, and has an inner peripheral face 120S and an
outer peripheral face 120T. The two latching portions 122 are
provided on the rear end face of the second rectilinear frame main
body 121, and protrude toward the rear. The two latching portions
122 are formed at substantially symmetrical positions around the
optical axis AX (see FIG. 3). As will be discussed below, when the
two latching portions 122 are latched to the third rectilinear
frame 130, the relative rotation of the third rectilinear frame 130
with respect to the second rectilinear frame 120 is checked. In
this embodiment, one of the two latching portions 122 is formed
longer in the peripheral direction than the other one.
[0333] The second rectilinear frame 120 has three rectilinear cam
followers AB2, three rectilinear grooves a4, and the bayonet groove
e2.
[0334] The three rectilinear cam followers AB2 are provided at the
rear end of the outer peripheral face 120T, and are disposed at a
substantially constant pitch in the peripheral direction. The three
rectilinear cam followers AB2 are engaged with the three cam
grooves b2 of the first rotary frame 210. Also, the three
rectilinear cam followers AB2 pass through the three cam grooves b2
and are engaged with the three rectilinear grooves a2 of the first
rectilinear frame 110.
[0335] The three rectilinear grooves a4 are formed in the inner
peripheral face 120S in the optical axis direction. The three
rectilinear grooves a4 are disposed at a substantially constant
pitch in the peripheral direction.
[0336] The bayonet groove e2 is formed at the rear end of the inner
peripheral face 120S. The bayonet groove e2 intersects the three
rectilinear grooves a4.
5. Configuration of Second Rotary Frame 220
[0337] FIG. 41 is an oblique view of the second rotary frame 220.
The second rotary frame 220 has a second rotary frame main body
221, three rectilinear protrusions A3, three bayonet protrusions
E2, two bayonet grooves e3, three cam grooves b3, three cam grooves
b4, three cam grooves b5, and three cam followers B6. In FIG. 41,
however, only two each of the cam grooves b3, the cam grooves b4,
and the cam grooves b5 are shown.
[0338] The second rotary frame main body 221 is formed in a
cylindrical shape, and has an inner peripheral face 220S and an
outer peripheral face 220T.
[0339] The three rectilinear protrusions A3 are provided at the
rear end of the outer peripheral face 220T, two of the three
rectilinear protrusions A3 are close together in the peripheral
direction, and the other one is separated by about 120.degree. or
more from the two rectilinear protrusions A3 that are close
together. The three rectilinear protrusions A3 are engaged with the
three rectilinear grooves a3 of the first rotary frame 210.
[0340] The three bayonet protrusions E2 are formed in the
peripheral direction at the rear end of the outer peripheral face
220T. The three bayonet protrusions E2 are disposed in front of the
three rectilinear protrusions A3. The bayonet protrusions E2 are
engaged with the bayonet groove e2 of the second rectilinear frame
120. In this embodiment, the bayonet protrusions E2 and the bayonet
groove e2 constitute a bayonet mechanism for rotatably engaging the
second rotary frame 220 with the second rectilinear frame 120.
[0341] The two bayonet grooves e3 are formed in the approximate
center of the inner peripheral face 220S in the peripheral
direction. The two bayonet grooves e3 are formed parallel to each
other. The two bayonet grooves e3 intersect with the cam grooves b4
and the cam grooves b5.
[0342] The three cam grooves b3 are formed in the outer peripheral
face 220T so as to intersect with the optical axis direction, and
are disposed at a substantially constant pitch in the peripheral
direction.
[0343] The cam grooves b4 and the cam grooves b5 are formed in the
inner peripheral face 220S. The cam grooves b4 and the cam grooves
b5 intersect each other.
6. Configuration of Third Rectilinear Frame 130
[0344] FIGS. 42A and 42B are oblique views of the third rectilinear
frame 130. The third rectilinear frame 130 has the third
rectilinear frame main body 131, the flange 132, and the two
latching recesses 133.
[0345] The third rectilinear frame main body 131 is formed in a
cylindrical shape, and has an inner peripheral face 130S and an
outer peripheral face 130T.
[0346] The flange 132 is formed in an annular shape, and is
provided on the rear end of the outer peripheral face 130T.
[0347] The two latching recesses 133 are cut-outs formed in the
outer edge of the flange 132. The two latching recesses 133 are
formed in substantially symmetrical positions around the optical
axis AX (see FIG. 3). FIG. 43 is a schematic diagram in which the
second rectilinear frame 120, the second rotary frame 220, and the
third rectilinear frame 130 have been put together. As shown in
FIG. 43, when the two latching portions 122 of the second
rectilinear frame 120 are latched to the two latching recesses 133
of the third rectilinear frame 130, relative rotation of the third
rectilinear frame 130 with respect to the second rectilinear frame
120 is checked. One of the two latching recesses 133 is formed
longer in the peripheral direction than the other one,
corresponding to the fact that one of the two latching portions 122
is formed longer in the peripheral direction than the other one.
This increases the strength of the two latching recesses 133.
[0348] The third rectilinear frame 130 has two bayonet protrusions
E3, three rectilinear grooves a5, and three rectilinear grooves a6.
In FIG. 42A, however, only two of the bayonet protrusions E3 are
shown.
[0349] The two bayonet protrusions E3 are formed in the peripheral
direction in the approximate center of the outer peripheral face
130T. Two of the bayonet protrusions E3 are formed parallel to each
other. The two bayonet protrusions E3 are engaged with the two
bayonet grooves e3 of the second rotary frame 220. In this
embodiment, the bayonet protrusions E3 and the bayonet grooves e3
constitute a bayonet mechanism for rotatably engaging the third
rectilinear frame 130 with the second rotary frame 220.
[0350] The three rectilinear grooves a5 pass through the third
rectilinear frame main body 131 from the inner peripheral face 130S
to the outer peripheral face 130T. The three rectilinear grooves a5
extend in the optical axis direction, and are disposed at a
substantially constant pitch in the peripheral direction.
[0351] The three rectilinear grooves a6 pass through the third
rectilinear frame main body 131 from the inner peripheral face 130S
to the outer peripheral face 130T. The three rectilinear grooves a6
extend in the optical axis direction, and are disposed at a
substantially constant pitch in the peripheral direction.
[0352] In this embodiment, the three rectilinear grooves a5 and the
three rectilinear grooves a6 are disposed alternately in the
peripheral direction.
[0353] As shown in FIG. 42A, the third rectilinear frame 130
further has the guide groove a7 (an example of a first cam portion)
formed in the inner peripheral face of the third rectilinear frame
main body 131, and the reinforcing portion 130H (shaded part)
formed near the guide groove a7.
[0354] The guide groove a7 guides the driven portion 411 (see FIG.
47A; discussed below) as a cam follower. The guide groove a7 and
the driven portion 411 constitute a cam mechanism for moving the
retracting lens frame 401. This cam mechanism changes the
orientation of the refracting lens frame 401 when the third
rectilinear frame 130 moves relative to the retracting lens frame
401 in the optical axis direction.
[0355] As shown in FIG. 42A, the guide groove a7 has a portion that
is inclined to the optical axis direction (inclined part) and a
portion is that parallel to the optical axis direction (parallel
part). When the driven portion 411 is guided by this inclined part,
the refracting lens frame 401 rotates around the retraction shaft
501b. The retracting lens frame 401 transitions between an image
blur correction enabled position and a retracted position by
rotating around the retraction shaft 501b.
[0356] The refracting lens frame 401 is biased by the rotary spring
403 from the refracted position toward the image blur correction
enabled position. More precisely, this biasing direction is around
the refraction shaft 501b, is perpendicular to the optical axis
direction, and is a direction in which the refracting lens frame
401 enters its imaging enabled state. Specifically, this biasing
direction is a direction in which the optical axis direction of the
third lens group L3 is aligned with the optical axis direction of
the other lenses.
[0357] Therefore, when the guide groove a7 and the driven portion
411 cause the retracting lens frame 401 to rotate against the
biasing force of the rotary spring 403, the driven portion 411
comes into contact with one side (one side face) of the guide
groove a7. The guide groove a7 is in the form of a groove.
Specifically, the guide groove a7 is made up of three faces. These
three faces constitute a side face on the front side in the optical
axis direction, a side face on the rear side in the optical axis
direction, and a bottom face that is parallel to the optical axis
direction and connects the first two faces. The contact face of the
guide groove a7 that comes into contact with the driven portion 411
is the side face on the rear side in the optical axis direction.
Therefore, the retracting lens frame 401 is rotated as long as the
side face on the rear side in the optical axis direction is
provided.
[0358] However, because the guide groove a7 is groove shaped, that
is, consists of three faces, the position of the driven portion 411
is reliably maintained by the guide groove a7 even if the camera is
dropped, subjected to an impact, etc., so the orientation of the
retracting lens frame 401 is kept stable. Furthermore, even if the
rotational load of the retracting lens frame 401 is increased over
the rotational force of the rotary spring 403 due to the influence
of wear through continuous use or of the adhesion of foreign matter
in the guide groove a7, the retracting lens frame 401 is forcibly
rotated.
[0359] The side face on the front side in the optical axis
direction and the side face on the rear side in the optical axis
direction of the guide groove a7 are formed in a tapered shape
(that is, a sloped face shape) with respect to the direction
perpendicular to the optical axis direction. The angle of the
sloped face to the direction perpendicular to the optical axis
direction is smaller for the side face on the rear side in the
optical axis direction than for the side face on the front side in
the optical axis direction. The smaller is the angle of the sloped
face to the direction perpendicular to the optical axis direction,
the less torque loss is produced by the rotational load.
[0360] As discussed above, during normal operation, that is, when
the camera is not dropped or otherwise subjected to impact, and
there is no adhered foreign matter, worn parts, etc., only the side
face on the rear side in the optical axis direction is in contact
with the driven portion 411. Accordingly, the above effect can be
obtained as long as at least the angle of the side face on the rear
side in the optical axis direction with respect to the direction
perpendicular to the optical axis is small.
[0361] Because the guide groove a7 that engages with the driven
portion 411 is formed in the third rectilinear frame 130, rotation
of the retracting lens frame 401 is started earlier during the
transition period between the imaging enabled state and the housed
state. If the guide groove a7 is provided to the stationary portion
of the imaging element holder or the like, the retracting lens
frame 401 usually is remote from the stationary portion in the
optical axis direction. Accordingly, during the transition period
between the imaging enabled state and the housed state, the guide
groove a7 and the retracting lens frame 401 cannot be instantly
engaged, and the rotation of the retracting lens frame 401 cannot
be started right away.
[0362] In contrast, if the guide groove a7 is provided to the third
rectilinear frame 130, then during the transition period between
the imaging enabled state and the housed state, the guide groove a7
and the driven portion 411 always are close enough to engage.
Accordingly, if the guide groove a7 is provided to the third
rectilinear frame 130, the rotation of the retracting lens frame
401 is started right away during the transition period between the
imaging enabled state and the housed state.
[0363] Also, because the guide groove a7 that engages with the
driven portion 411 is formed in the third rectilinear frame 130,
this improves the rotational accuracy of the refracting lens frame
401. For example, if the guide groove a7 is provided to the
stationary portion of the imaging element holder or the like, there
is the risk that more parts will be in between the driven portion
411 and the guide groove a7. The more of these parts there are, the
worse is the relative positional accuracy of the refracting lens
frame 401. In contrast, if the guide groove a7 is provided to the
third rectilinear frame 130, there are relatively few parts in
between the driven portion 411 and the guide groove a7, so the
relative positional accuracy of the refracting lens frame 401 is
increased.
[0364] Also, as discussed above, if the guide groove a7 is provided
to the stationary portion of the imaging element holder or the
like, there will be more parts in between the driven portion 411
and the guide groove a7, so this adversely affects the relative
rotational accuracy of the refracting lens frame 401. Furthermore,
if the refracting lens frame 401 is mounted to the OIS frame 400 so
as to be rotatable around an axis parallel to the optical axis,
there is a further loss of relative rotational accuracy between the
driven portion 411 and the guide groove a7. To put this another
way, if a refraction mechanism is constituted and the OIS frame 400
is mounted to the shutter frame 335 so as to be able to operate in
a plane perpendicular to the optical axis (that is, if an image
blur correction mechanism is constituted), there is a further loss
of relative rotational accuracy between the driven portion 411 and
the guide groove a7. However, if the guide groove a7 is provided to
the third rectilinear frame 130, there is relatively few parts in
between the driven portion 411 and the guide groove a7, so there is
better relative rotational accuracy of the refracting lens frame
401.
[0365] Also, because the guide groove a7 that engages with the
driven portion 411 is formed in the third rectilinear frame 130,
the guide groove a7 is easily constituted by three faces, namely,
the side face on the front side in the optical axis direction, the
side face on the rear side in the optical axis direction, and the
face (bottom face) that is parallel to the optical axis and
connects the above-mentioned two faces.
[0366] On the other hand, if the guide groove a7 is provided to the
stationary portion of the imaging element holder or the like, the
guide groove a7 has to be formed in the stationary portion of the
imaging element holder. Here, if an attempt is made to form the
three faces constituting the guide groove a7 in the stationary
portion of the imaging element holder, then the stationary portion
of the imaging element holder or the like ends up being larger.
Also, if the guide groove a7 is formed in a small space in order to
avoid making the stationary portion of the imaging element holder
larger, then the guide groove a7 does not be strong enough.
[0367] However, if the guide groove a7 is provided to the third
rectilinear frame 130, since the third rectilinear frame 130 is
cylindrical, it is easy to provide the three faces of the guide
groove a7. Also, in this case there is no need to form the guide
groove a7 in the stationary portion of the imaging element holder
or the like, so there is no need to make the stationary portion of
the imaging element holder larger. Also, in this case, since the
portion where the guide groove a7 is formed is cylindrical, the
strength of the guide groove a7 can also be improved.
[0368] Furthermore, because the guide groove a7 that engages with
the driven portion 411 is formed in the third rectilinear frame
130, centering during retraction can be performed more accurately.
If the guide groove a7 is provided to the third rectilinear frame
130, a mechanism for centering the OIS frame 400 also is formed in
the third rectilinear frame 130. Accordingly, there is better
positional accuracy of the retracting lens frame 401 and the OIS
frame 400.
[0369] The reinforcing portion 130H is formed locally on the third
rectilinear frame main body 131. The reinforcing portion 130H is
formed on the inner peripheral face of the third rectilinear frame
main body 131. More specifically, the reinforcing portion 130H is
formed on the third rectilinear frame main body 131 so as to
protrude toward the inside of the third rectilinear frame main body
131. That is, using the outer peripheral face of the third
rectilinear frame main body 131 as a reference, the reinforcing
portion 130H is formed so that the thickness of the reinforcing
portion 130H increases toward the inner peripheral side over the
thickness of the other portion. The reinforcing portion 130H is
formed near the guide groove a7, such as adjacent to the guide
groove a7.
[0370] The thickness of the reinforcing portion 130H is determined
by the depth of the guide groove a7. Specifically, the thickness of
the reinforcing portion 130H is set so that the depth of the guide
groove a7 (the radial direction dimension of the guide groove a7)
fits in the reinforcing portion 130H. The depth of the guide groove
a7 is determined by the size (height) of the driven portion 411
inserted into the guide groove a7. The depth of the guide groove a7
(the radial direction dimension of the guide groove a7) is set so
as to accommodate the height of the driven portion 411 (the radial
direction dimension of the driven portion 411).
[0371] The thickness of the third rectilinear frame main body 131
is preferably as thin as possible in order to reduce the outside
diameter of the lens barrel 20. However, the cam mechanism for
moving the retracting lens frame 401, that is, the portion where
the guide groove a7 and the driven portion 411 engage, needs to be
strong, so a certain amount of thickness is necessary. If this
portion having a certain thickness is formed on the inner
peripheral face side of the third rectilinear frame main body 131,
the outside diameter of the third rectilinear frame main body 131
is kept from becoming larger. Specifically, an increase in the
outside diameter of the lens barrel 20 is suppressed.
[0372] As shown in FIG. 42B, the third rectilinear frame 130 has
three shunting grooves a9 for restricting movement of the OIS frame
400 with respect to the shutter frame 335 or the third rectilinear
frame 130. The three shunting grooves a9 are formed in the inner
peripheral face 130S of the third rectilinear frame main body 131.
The three shunting grooves a9 are formed in the third rectilinear
frame main body 131 spaced a specific distance apart from each
other in the peripheral direction on the inner peripheral face
130S.
[0373] The three shunting grooves a9 are grooves extending in the
optical axis direction. The shunting grooves a9 are formed so that
the groove part is larger on the flange 132 side. More
specifically, the shunting grooves a9 have a first groove a91, a
second groove a92, and a third groove a93. The first groove a91 and
the second groove a92 are such that the shape of their cross
section perpendicular to the optical axis is semicircular,
semi-elliptical, trapezoidal, rectangular, parabolic, or a
combination of these.
[0374] The first groove a91 is a groove part formed on the flange
132 side. The width and depth of the first groove a91 are greater
than the width and depth of the second groove a92. The third groove
a93 is in the form of a sloped face, a conical face, a curved face,
or a shape that is a combination of these, so as to smoothly change
from the width and depth of the first groove a91 to the width and
depth of the second groove a92. When the shunting protrusions 404
(see FIG. 48A) of the OIS frame 400 (discussed below) are disposed
in the first grooves a91, the shunting protrusions 404 are movable
inside the first grooves a91. Specifically, in this case the OIS
frame 400 is movable within a plane perpendicular to the optical
axis with respect to the third rectilinear frame 130 or the shutter
frame 335.
[0375] The second groove a92 is a groove part extending in the
optical axis direction from the first groove a91. When the shunting
protrusions 404 (see FIG. 48A) of the OIS frame 400 (discussed
below) are disposed in the second grooves a92, the OIS frame 400 is
constricted in the radial direction and the peripheral direction
with respect to the third rectilinear frame 130 or the shutter
frame 335. Consequently, movement of the OIS frame 400 is
restricted with respect to the third rectilinear frame 130 or the
shutter frame 335.
[0376] The third groove a93 is a groove part extending in the
optical axis direction, and links the first groove a91 and the
second groove a92. When the shunting protrusions 404 (see FIG. 48A)
of the OIS frame 400 (discussed below) are disposed in the third
grooves a93, the OIS frame 400 transitions from a state of being
movable within a plane perpendicular to the optical axis with
respect to the third rectilinear frame 130 or the shutter frame
335, to a state of being gradually restricted in the radial
direction and the peripheral direction.
[0377] Specifically, when the shunting protrusions 404 of the OIS
frame 400 are disposed from the first grooves a91, via the third
grooves a93, in the second grooves a92, this centers the OIS frame
400.
[0378] The mechanism for centering the OIS frame 400 (centering
mechanism) is constituted by the shunting grooves a9 (a91, a92, and
a93) of the third rectilinear frame 130 and the shunting
protrusions 404 of the OIS frame 400.
7. Configuration of First Lens Group Frame 310
[0379] FIG. 44 is an oblique view of the first lens group frame
310. The first lens group frame 310 has a first lens group frame
main body 311, three rectilinear protrusions A4, and three cam
followers B3.
[0380] The first lens group frame main body 311 is formed in a
cylindrical shape, and has an inner peripheral face 310S and an
outer peripheral face 310T. Three protrusions 311a that protrude
toward the rear are formed on the first lens group frame main body
311.
[0381] The three rectilinear protrusions A4 are provided to the
outer peripheral face 310T of the protrusions 311a, and are
disposed at a substantially constant pitch in the peripheral
direction. The three rectilinear protrusions A4 are engaged with
the three rectilinear grooves a4 of the second rectilinear frame
120.
[0382] The three cam followers B3 are provided to the inner
peripheral face 310S of the protrusions 311a, and are disposed at a
substantially constant pitch in the peripheral direction. The three
cam followers B3 are engaged with the three cam grooves b3 of the
second rotary frame 220.
[0383] In this embodiment, the three rectilinear protrusions A4 and
the three cam followers B3 are disposed substantially opposite each
other, with the protrusions 311a in between.
8. Configuration of Second Lens Group Frame 320
[0384] FIG. 45A is an oblique view of the second lens group frame
320. FIG. 45B is a view of the second lens group frame 320 from the
front. FIG. 45C is an oblique view of the relation between the
second lens group frame 320 and the sheet member 324. As shown in
FIG. 45A, the second lens group frame 320 has a second lens group
frame main body 321, a second lens support 321L for supporting the
second lens group L2, a housing receptacle 322 (an example of a
restrictor that restricts movement of the retracting lens frame
401; discussed below), a housing portion 323, three rectilinear
protrusions A5, and three cam protrusions B4.
[0385] The second lens group frame main body 321 is formed in a cup
shape, and has an outer peripheral face 320T.
[0386] The housing receptacle 322 is used to position the
retracting lens frame 401 by restricting movement of the retracting
lens frame 401 during the transition period between the imaging
enabled state and the housed state, and coming into contact with
the positioning portion 412 of the retracting lens frame 401. As
shown in FIG. 45A, the housing receptacle 322 is formed integrally
with the second lens group frame main body 321. More precisely, the
housing receptacle 322 is formed integrally with the second lens
group frame main body 321 on the outer peripheral part of the
second lens support 321L (the portion supporting the second lens
group L2). The housing receptacle 322 has the guide portion 322a
that guides the 301 to the refracted position by coming into
contact with the positioning portion 412 of the retracting lens
frame 401, and the support portion 322b that supports the
refracting lens frame 401 at the retracted position (see FIG.
50A).
[0387] The guide portion 322a has a sloped face. The sloped face is
formed so that the distance from the optical axis AX decreases
moving toward the imaging element side along the optical axis
AX.
[0388] The cam mechanism constituted by the guide groove a7 and the
driven portion 411 is such that the third rectilinear frame 130
moves relatively in the optical axis direction with respect to the
refracting lens frame 401, which changes the orientation of the
retracting lens frame 401. After this, the positioning portion 412
of the refracting lens frame 401 is brought into contact with the
guide portion 322a (sloped face), which guides the refracting lens
frame 401 to the refracted position.
[0389] The support portion 322b is a portion extending in the
optical axis direction, and supports the refracting lens frame 401.
As discussed above, the positioning portion 412 of the refracting
lens frame 401 guided by the guide portion 322a is supported in a
state of being in contact with the support portion 322b.
[0390] As shown in FIGS. 45A to 45C, the housing portion 323 is a
portion for housing at least part of the OIS frame 400 and the
refracting lens frame 401 in the refracted state. The housing
portion 323 has a first housing portion 323a and a second housing
portion 323b. The first housing portion 323a is used to house a
second linking portion 408 of the OIS frame 400 (discussed below).
The first housing portion 323a is a hole provided on the front face
side of the second lens group frame main body 321. The first
housing portion 323a is provided above the second lens group L2.
The first housing portion 323a is formed in a shape substantially
similar to the outer shape of the second linking portion 408.
[0391] At least part of the first housing portion 323a and at least
part of the second linking portion 408 overlap in the optical axis
direction. This allows the size of the lens barrel 20 to be smaller
in the optical axis direction in the housed state.
[0392] The second housing portion 323b is used to house the
refraction shaft 501b. The second housing portion 323b is a hole
provided on the front face side of the second lens group frame main
body 321. The second housing portion 323b is formed in a
substantially circular shape.
[0393] As shown in FIG. 45B, the sheet member 324 is affixed to the
front face of the second lens group frame 320. The sheet member 324
prevents light from leaking out of the hole in the front face of
the second lens group frame 320 (including the housing portion
323).
[0394] The three rectilinear protrusions A5 are formed on the rear
end of the outer peripheral face 320T, and are disposed at a
substantially constant pitch in the peripheral direction. The three
rectilinear protrusions A5 are engaged with the three rectilinear
grooves a5 of the third rectilinear frame 130.
[0395] The three cam protrusions B4 are formed on the three
rectilinear protrusions A5. The three cam protrusions B4 are
engaged with the three cam grooves b4 of the second rotary frame
220.
9. Configuration of Third Lens Group Frame 330
[0396] FIG. 46A shows the state when the third lens group frame 330
has been housed in the interior of the shutter frame 335. The
configuration of the third lens group frame 330 will be described
through reference to FIG. 46A.
[0397] The third lens group frame 330 (an OIS (optical image
stabilizer) unit) mainly has the OIS frame 400 (an example of a
support frame), the refracting lens frame 401, the thrust spring
402 (an example of a first biasing means), the rotary spring 403
(an example of a second biasing means, and an example of a biasing
member), and the third lens group L3 for image blur correction.
[0398] As shown in FIGS. 46A and 47A, the OIS frame 400 is mounted
to the shutter frame 335. The optical axis direction position of
the OIS frame 400 with respect to the shutter frame 335 is
maintained because three OIS shafts 339 that are press-fitted to
the shutter frame 335 are inserted into optical axis direction
maintenance portions 415 at three places on the OIS frame 400 (only
two of the optical axis direction maintenance portions 415 are
shown in FIG. 47A). As shown in FIG. 47A, the position of the OIS
frame 400 in a direction perpendicular to the optical axis with
respect to the shutter frame 335 is maintained because one OIS
rotary shaft 334 press-fitted to the shutter frame 335 is inserted
into a perpendicular direction maintenance portion 416 at one place
on the OIS frame 400 in the optical axis direction, and an optical
axis direction stopper pin 409 comes into contact with the
peripheral wall of a movable range restrictor 338 of the OIS frame
400 (see FIG. 51B).
[0399] As shown in FIGS. 47A and 48A, a space ST is formed in the
OIS frame 400 in order to house the third lens support 420 that
supports the third lens group L3 supported by the refracting lens
frame 401 in the imaging enabled state. When the refracting lens
frame 401 has been refracted, the second lens support 321L of the
second lens group frame 320 is housed in this space ST.
[0400] The OIS frame 400 also has a main body portion 405, a first
linking portion 407, and the second linking portion 408. The main
body portion 405 has a hole 405a and a first cut-out 405b (an
example of a cut-out in the OIS frame 400).
[0401] The hole 405a forms the above-mentioned space ST. The hole
405a is formed in the center of the main body portion 405. The
third lens support 420 that supports the third lens group L3 in the
imaging enabled state is disposed in the hole 405a. The hole 405a
also houses the second lens support 321L of the second lens group
frame 320 when refracted.
[0402] The first cut-out 405b is formed contiguous with the hole
405a. The first cut-out 405b is formed on the outer peripheral part
of the main body portion 405.
[0403] The first linking portion 407 serves to increase the
strength of the main body portion 405. The first linking portion
407 is formed integrally with the main body portion 405. More
specifically, the first linking portion 407 is formed integrally
with the main body portion 405, spanning to the first cut-out 405b,
on the shutter frame 335 side of the main body portion 405.
[0404] Also, as shown in FIGS. 46B and 47B, the portion of the
shutter frame 335 that is opposite the first linking portion 407 at
the face of a shutter frame main body 336 on the front side in the
optical axis direction is locally made thinner, and the first
linking portion 407 goes into this thinner part 350. Specifically,
at least part of the shutter frame 335 and at least part of the
first linking portion 407 overlap in the optical axis direction.
This allows the lens barrel 20 to be even smaller in the optical
axis direction.
[0405] The protrusions 404 (see FIG. 48A) used to center the OIS
frame 400 substantially at an optical axis position protrude in the
radial direction from the side faces of the OIS frame 400. The side
wall holes 351 are provided in the shutter frame main body 336 side
walls as shown in FIG. 47A in order to insert these protrusions 404
into the side walls of the shutter frame main body 336. The OIS
frame 400 comprises side walls 417 that substantially cover the
side wall holes 351 in the shutter frame main body 336. This
prevents light from leaking through the side wall holes 351 in the
shutter frame main body 336.
[0406] As shown in FIG. 46B, three light blocking walls 352 that
protrude in the radial direction are formed on the side faces of
the shutter frame main body 336. The peripheral direction positions
of the three light blocking walls 352 correspond to the peripheral
direction positions of the three rectilinear grooves a6 of the
third rectilinear frame 130. The peripheral direction width of the
three light blocking walls 352 is substantially the same as or less
than the peripheral direction width of the three rectilinear
grooves a6 of the third rectilinear frame 130. This prevents light
from leaking out through the three rectilinear grooves a6 of the
third rectilinear frame 130.
[0407] As shown in FIG. 48A, the OIS frame 400 has the shunting
protrusions 404 that engage with the shunting grooves a9 of the
third rectilinear frame 130. The shunting protrusions 404 are
formed integrally with the main body portion 405 of the OIS frame
400. More specifically, the two shunting protrusions 404 are formed
on the main body portion 405 so as to protrude outward from the
outer peripheral part of the main body portion. Also, the two
shunting protrusions 404 are formed integrally with the main body
portion 405, spaced apart by a specific distance, around the outer
peripheral part of the main body portion 405. The two shunting
protrusions 404 are specially fitted into and guided by the two
shunting grooves a9 of the third rectilinear frame 130.
[0408] More specifically, when the OIS frame 400 moves closer to
the third rectilinear frame 130 in a state in which the OIS frame
400 has been mounted to the shutter frame 335, the shunting
protrusions 404 formed on the OIS frame 400 are introduced from the
flange 132 side of the third rectilinear frame 130 into the first
grooves a91 of the third rectilinear frame 130. In a state in which
the shunting protrusions 404 are disposed in the first grooves a91,
the OIS frame 400 is movable within a plane perpendicular to the
third rectilinear frame 130 or the shutter frame 335.
[0409] Then, when the OIS frame 400 moves further in the optical
axis direction on the inner peripheral side of the third
rectilinear frame 130 in a state in which the OIS frame 400 has
been mounted to the shutter frame 335, the shunting protrusions 404
are guided into the third grooves a93. As a result, the OIS frame
400 transitions from a state of being movable within a plane
perpendicular to the optical axis with respect to the third
rectilinear frame 130 or the shutter frame 335, to a state of being
gradually restricted in the radial direction and the peripheral
direction.
[0410] When the shunting protrusions 404 are then introduced into
the second grooves a92, the second grooves a92 press the shunting
protrusions 404 away from the inner peripheral face 130S of the
third rectilinear frame 130. Consequently, movement of the OIS
frame 400 is restricted in a plane perpendicular to the optical
axis with respect to the third rectilinear frame 130 or the shutter
frame 335. This centers the OIS frame 400.
[0411] When the shunting protrusions 404 are then introduced into
the second grooves a92, the second grooves a92 press the shunting
protrusions 404 away from the inner peripheral face 130S of the
third rectilinear frame 130. Consequently, movement of the OIS
frame 400 is restricted in a plane perpendicular to the optical
axis with respect to the third rectilinear frame 130 or the shutter
frame 335. This centers the OIS frame 400.
[0412] When the shunting protrusions 404 are guided by the third
grooves a93 of the third rectilinear frame 130, the third
rectilinear frame 130 is positioned away from the shunting grooves
a9. The refraction of the retracting lens frame 401 begins in this
state. Specifically, the driven portion 411 of the retracting lens
frame 401 is guided by the guide groove a7 of the third rectilinear
frame 130. The drive force received by the driven portion 411 of
the refracting lens frame 401 from the guide groove a7 then acts in
the direction of pressing on the shunting grooves a9. This reliably
restricts looseness between the shunting protrusions 404 and the
shunting grooves a9. That is, the OIS frame 400 is reliably
centered.
[0413] The centering of the OIS frame 400 in this embodiment is
carried out before the refracting lens frame 401 begins to refract,
but what is important is that the centering be completed by the
time the refraction operation is complete.
[0414] In a state in which the OIS frame 400 has been mounted to
the shutter frame 335, the first linking portion 407 is disposed
above the magnets 521 and the coil 522 (actuator) that are
discussed below.
[0415] The second linking portion 408 is provided to increase the
strength of the main body portion 405 and to block light to the
imaging element side. That is, the second linking portion 408 is
also used as a light blocking portion. The second linking portion
408 is formed integrally with the main body portion 405. More
specifically, the second linking portion 408 is formed integrally
with the main body portion 405, spanning to the first cut-out 405b,
on the subject side of the main body portion 405.
[0416] The second linking portion 408 is provided at a position
that is a specific distance away from the main body portion 405.
Also, the second linking portion 408 is provided at a position that
is a specific distance away from the first linking portion 407.
[0417] When the refracting lens frame 401 is in its refracted state
(housed state), the third lens support 420 that supports the third
lens group L3 is disposed in the cut-out 405b between the first
linking portion 407 and the second linking portion 408.
[0418] The OIS frame 400 is movable in a plane perpendicular to the
optical axis. More specifically, the magnets 521 are fixed to the
OIS frame 400, and the coil 522 is fixed to the shutter frame 335
at a position opposite the magnets 521. In this state, when power
is supplied from a camera circuit (not shown) to the coil 522 of
the shutter frame 335, current flows to the coil 522 and a magnetic
field is generated. This magnetic field drives the magnets 521 of
the OIS frame 400, and this drive force causes the OIS frame 400 to
move within a plane perpendicular to the optical axis.
[0419] As shown in FIG. 48A, the OIS frame 400 further has three
rail portions 503. The three rail portions 503 (503a to 503c) are
formed on the main body portion 405. The rail portions 503 are
formed on one face of the substantially disk-shaped main body
portion 405. The rail portions 503 are formed on the main body
portion 405 at positions opposite a contact portion 603 formed on
the retracting lens frame 401 (the first contact face 603A
discussed below).
[0420] The rail portions 503 are formed on the portion of the main
body portion 405 excluding the range where the third lens group L3
supported by the retracting lens frame 401 moves. Furthermore, the
rail portions 503 are formed in a shape corresponding to the path
over which the contact face 603 discussed below (the first contact
face 603A) moves when the lens barrel 20 transitions from the
imaging enabled state to the refracted state.
[0421] As shown in FIGS. 48A and 48B, the OIS frame 400 further has
an anti-rotation portion 511. The anti-rotation portion 511 is used
to position the retracting lens frame 401 in the imaging enabled
state. The anti-rotation portion 511 is formed integrally with the
outer peripheral part of the main body portion 405.
[0422] As shown in FIG. 48B, a recess 512 is formed in the
anti-rotation portion 511. A second contact face 603B of the
refracting lens frame 401 (discussed below) comes into contact with
one of two side walls 512a of the recess 512. More specifically,
the side walls 512a are formed at positions a specific distance
away from the surface of the main body portion 405. These side
walls 512a are sloped so that they move closer to the opposite side
wall (the surface of the main body portion 405) as they move toward
the bottom of the recess 512. This sloping pushes the second
contact face 603B of the retracting lens frame 401 toward the OIS
frame 400, and presses the second contact face 603B of the
retracting lens frame 401 against the contact face 512c of the OIS
frame 400.
[0423] As shown in FIG. 47A, the refracting lens frame 401 is
supported by the OIS frame 400 so as to be movable around the
refraction shaft 501b, which is substantially parallel to the
optical axis. The retracting lens frame 401 supports the third lens
group L3 used to image blur correction with the third lens support
420. The third lens group L3 is made up of one or more lenses.
[0424] The term "refraction shaft" as used below will sometimes be
used in the sense of "the axis of the refraction shaft."
[0425] As shown in FIG. 47A, the refracting lens frame 401 has the
main body portion 401a, the bearing 410, the driven portion 411,
the positioning portion 412 (see FIGS. 50A and 52), the third lens
support 420, and an engagement portion 413. The bearing 410 is
formed integrally with the main body portion 401a.
[0426] As shown in FIGS. 47A and 48A, the bearing 410 is rotatably
mounted to the support shaft 501b (refraction shaft) provided to
the OIS frame 400. As shown in FIGS. 49A and 49B, a hole into which
the refraction shaft 501b is inserted is formed in the bearing 410.
At least two contact faces 601a that come into contact with the
retraction shaft 501b are formed in the hole of the bearing 410. In
other words, the two contact faces 601a are formed in the inner
peripheral face of the bearing 410.
[0427] The two contact faces 601a are formed on the proximal end
side of the retraction shaft 501b, that is, on the inner peripheral
face of the bearing 410 on the opening side of the bearing 410
(hole). The two contact faces 601a are formed on the inner
peripheral face of the bearing 410 so as to be in a mutually
non-parallel relation. More specifically, when the bearing 410
(hole) is viewed in the depth direction, the two contact faces 601a
are formed on the inner peripheral face of the bearing 410 so as to
form an angle.
[0428] As shown in FIG. 49B, the two contact faces 601a
(hereinafter referred to as V-faces) come into contact with the
outer peripheral face of the retraction shaft 501b. More
specifically, the refracting lens frame 401 is biased by the
biasing force F0 of the rotary spring 403 (see FIG. 49A), and the
component force F1 of this biasing force F0 brings the V-faces 601a
of the bearing 410 into contact with the outer peripheral face of
the retraction shaft 501b.
[0429] As discussed below, in this embodiment, the other end 403b
of the rotary spring 403 is bent. When the other end 403b of the
rotary spring 403 is thus formed, the component force F1, that is,
the force at which the contact faces 601a of the bearing 410 are
brought into contact with the outer peripheral face of the
refraction shaft 501b, is increased over that when the other end
403b of the rotary spring 403 is formed straight. This allows the
refraction shaft 501b to be reliably positioned with respect to the
bearing 410 of the retracting lens frame 401. More precisely,
accuracy with respect to eccentricity of the refraction shaft 501b
can be increased. The component forces of the biasing force F0 in
FIG. 49A are F1 and F2.
[0430] The driven portion 411 is the portion that is driven against
the biasing force of the rotary spring 403 (discussed below) during
the transition period between the imaging enabled state and the
housed state. As shown in FIGS. 47A and 52, the driven portion 411
is formed integrally and protruding outward from the main body
portion 401a. The driven portion 411 engages with the guide groove
a7 formed in the inner peripheral face of the third rectilinear
frame 130. More precisely, the driven portion 411 engages with the
guide groove a7 of the third rectilinear frame 130 via an opening
SK1 (discussed below) in the shutter frame 335. The driven portion
411 moves relatively in the optical axis direction with respect to
the refracting lens frame 401, and is thereby guided in the guide
groove a7 of the third rectilinear frame 130. This changes the
orientation of the retracting lens frame 401 between the imaging
enabled state and the refracted state.
[0431] The positioning portion 412 is formed on the portion (the
third lens support 420) of the refracting lens frame 401 that
supports the third lens group L3. The positioning portion 412 is
positioned in the housing receptacle 322 of the second lens group
frame 320 during the transition period between the imaging enabled
state and the housed state.
[0432] The positioning portion 412 is formed so that the distance
between the positioning portion 412 and the refraction shaft 501b
becomes greater than the distance between the driven portion 411
and the refraction shaft 501b. More precisely, as shown in FIG.
47A, the positioning portion 412 is formed so that the distance LK1
between the axis of the refraction shaft 501b and the position
where the positioning portion 412 comes into contact with the
housing receptacle 322 becomes greater than the distance LK2
between the axis of the refraction shaft 501b and the proximal end
of the driven portion 411.
[0433] As shown in FIGS. 47A, 50A, and 50B, the third lens support
420 is the portion that supports the third lens group L3. The third
lens support 420 is in the form of a cylinder. The third lens group
L3 is mounted on the inside of the third lens support 420.
[0434] As shown in FIG. 50B, the third lens support 420 has a
second cut-out 420a. The second cut-out 420a is provided to the
outer peripheral part of the third lens support 420. More
specifically, the second cut-out 420a is a portion that is
partially cut away from the outer peripheral part of the third lens
support 420. More precisely, at the second cut-out 420a, the side
of the outer peripheral part of the third lens support 420 that is
away from the optical axis in the imaging enabled state when the
retracting lens frame 401 is in the retracted state is cut away.
The cut-out 420a is disposed opposite a light blocking portion 357
(see FIG. 47A) of the shutter frame 335 (discussed below) during
the transition period between the imaging enabled state and the
housed state.
[0435] As shown in FIGS. 47A and 51C, the third lens support 420 is
disposed between the second linking portion 408 and the face on the
front side in the optical axis direction of the shutter frame main
body 336 of the shutter frame 335 during the transition period
between the imaging enabled state and the housed state. Also, the
third lens support 420 is disposed between the second linking
portion 408 and the first linking portion 407 when it has entered
the thinner part 350 of the face on the front side in the optical
axis direction of the shutter frame main body 336. At least part of
the shutter frame 335 overlaps at least part of the first linking
portion 407 in the optical axis direction. This allows the lens
barrel 20 to be smaller in the optical axis direction in its housed
state.
[0436] As shown in FIGS. 51A to 51C, a first engagement portion
413a is a portion capable of engaging with a first restrictor 337a
of the shutter frame 335 (discussed below). Also, a second
engagement portion 413b is a portion capable of engaging with the
second linking portion 408 of the OIS frame 400 (discussed below).
The engagement portions here constitute the first engagement
portion 413a that engages with the first restrictor 337a (discussed
below), and the second engagement portion 413b that engages with
the second linking portion 408, which acts as a restrictor during
the transition period between the imaging enabled state and the
housed state.
[0437] As shown in FIGS. 51A and 51B, the first engagement portion
413a is formed near the refraction shaft 501b. As shown in FIG.
51B, the first engagement portion 413a is disposed between the
first restrictor 337a and the OIS frame 400. The second engagement
portion 413b is formed on the third lens support 420 that supports
the third lens group L3. The second engagement portion 413b is
disposed opposite the second linking portion 408 formed on the OIS
frame 400, during the transition period between the imaging enabled
state and the housed state.
[0438] As shown in FIG. 52, the refracting lens frame 401 further
has the plurality of contact portions 603 (603A and 603B). The
contact portions 603 are formed integrally with the main body
portion 401a of the refracting lens frame 401. The contact portions
603 are made up of three first contact portions 603A (603A1, 603A2,
and 603A3) and a second contact portion 603B.
[0439] The three first contact portions 603A and the second contact
portion 603B are formed integrally with the main body portion 401a
at a different position from the bearing 410. In other words, the
three first contact portions 603A and the second contact portion
603B are formed on the main body portion 401a at a different
position from that of the refraction shaft 501b supported by the
bearing 410. Also, the three first contact portions 603A and the
second contact portion 603B are formed on the main body portion
401a at a different position from that of the refraction shaft 501b
so as to be capable of contact with the OIS frame 400.
[0440] More precisely, the two contact portions 603A1 and 603A2 out
of the three first contact portions 603A are formed on the main
body portion 401a near the refraction shaft 501b. The two contact
portions 603A1 and 603A2 are formed on the main body portion 401a
so that the refraction shaft 501b is disposed between the two
contact portions 603A1 and 603A2. The other first contact portion
603A3 besides these two contact portions 603A1 and 603A2, and the
second contact portion 603B are formed on the main body portion
401a at a position that is away from the refraction shaft 501b.
[0441] The three first contact portions 603A (603A1, 603A2, and
603A3) are able to come into contact with the OIS frame 400.
Specifically, movement of the refracting lens frame 401 in the
optical axis direction is restricted when the three first contact
portions 603A come into contact with the OIS frame 400.
[0442] More precisely, when the three first contact portions 603A
come into contact with the rail portions 503 of the OIS frame 400
(see FIG. 48A), movement of the refracting lens frame 401 in the
optical axis direction is restricted. More specifically, when the
lens barrel 20 is in its imaging enabled state, the three first
contact portions 603A1, 603A2, and 603A3 come into contact with the
rail portions 503a, 503b, and 503c of the OIS frame 400. The first
contact portion 603A1 comes into contact with the rail portion
503a, the first contact portion 603A2 comes into contact with the
rail portion 503b, and the first contact portion 603A3 comes into
contact with the rail portion 503c.
[0443] When the three first contact portions 603A thus come into
contact with the rail portions 503 of the OIS frame 400, this
restricts movement of the retracting lens frame 401 in the optical
axis direction.
[0444] The second contact portion 603B shown in FIG. 52 is used to
position the retracting lens frame 401 on the OIS frame 400. The
second contact portion 603B comes into contact with the
anti-rotation portion 511 of the OIS frame 400 in the imaging
enabled state. The outer peripheral part of the second contact
portion 603B is formed so as to be able to mate with the
anti-rotation portion 511 of the OIS frame 400. For example, the
outer peripheral part of the second contact portion 603B is formed
in a tapered shape (see FIG. 48B). When the second contact portion
603B is fitted into the recess 512 of the anti-rotation portion 511
of the OIS frame 400, the retracting lens frame 401 is reliably
positioned in the imaging enabled state.
[0445] As shown in FIG. 47A, the thrust spring 402 is a spring that
biases the retracting lens frame 401 in the optical axis direction
with respect to the OIS frame 400. The thrust spring 402 is formed
in an approximate C shape. One end of the thrust spring 402 is
mounted to the OIS frame 400, and the other end of the thrust
spring 402 is mounted to the retracting lens frame 401.
[0446] Consequently, the retracting lens frame 401 and the OIS
frame 400 are clamped by the thrust spring 402 in the optical axis
direction.
[0447] As shown in FIG. 47A, the rotary spring 403 is a spring that
biases the retracting lens frame 401 around a retraction shaft 510,
that is, in a direction perpendicular to the optical axis. The
rotary spring 403 is supported by the OIS frame 400. The rotary
spring 403 is a torsion coil spring, for example. The coil part of
the rotary spring 403 is disposed on the outer periphery of the
bearing 410.
[0448] One end 403a of the rotary spring 403 is clamped by latching
portions 504a and 504b (see FIG. 48A) formed on the OIS frame 400.
As shown in FIG. 49A, the other end 403b of the rotary spring 403
is mounted in a groove 605 formed in the retracting lens frame 401.
The other end 403b of the rotary spring 403 is bent in two
stages.
[0449] As shown in FIG. 49A, the other end 403b of the rotary
spring 403 has a first bent part 403b1 formed on the distal end
side, and a second bent part 403b2 formed in the middle. The first
bent part 403b1 and the second bent part 403b2 are bent so as to
conform to the outer shape of the third lens support 420 of the
refracting lens frame 401. In this case, the first bent part 403b1
is mounted in the groove 605 formed in the refracting lens frame
401.
[0450] As shown in FIG. 49A, the first bent part 403b1 and the
second bent part 403b2 are bent so that a specific angle .alpha. is
formed by a specific straight line (horizontal line) passing
through the axis of the retraction shaft 501b, and the first bent
part 403b1 of the other end 403b of the rotary spring 403.
[0451] Thus forming the other end 403b of the rotary spring 403
increases the force (component force F1) at which the contact faces
601a of the bearing 410 come into contact with the outer peripheral
face of the refraction shaft 501b, as discussed above. This allows
the refraction shaft 501b to the reliably positioned with respect
to the bearing 410 of the refracting lens frame 401.
[0452] Because the rotary spring 403 biases the refracting lens
frame 401 as discussed above, the second contact portion 603B of
the refracting lens frame 401 comes into contact with the
anti-rotation portion 511 of the OIS frame 400 (see FIGS. 46A and
46B). The refracting lens frame 401 is positioned with respect to
the OIS frame 400 when the retracting lens frame 401 is mounted to
the retraction shaft 501b of the OIS frame 400, and the second
contact portion 603B comes into contact with the anti-rotation
portion 511 of the OIS frame 400.
[0453] As shown in FIGS. 50A and 50B, the position of the
refracting lens frame 401 is changed from a correction enabled
position in which the third lens group L3 executes image blur
correction (first orientation), to a retracted position in which
the third lens group L3 has been refracted from the optical axis
(second orientation). The retracting lens frame 401 supports the
third lens group L3, which is made up of at least one lens.
[0454] As shown in FIG. 50A, when the refracting lens frame 401 is
in the correction enabled position, the center of the second lens
group L2 and the center of the third lens group L3 are located on
the optical axis AX.
[0455] When the refracting lens frame 401 begins to retract, the
refracting lens frame 401 and the second lens support 321L of the
second lens frame 320 move closer together while the refracting
lens frame 401 rotates. This causes the positioning portion 412 of
the retracting lens frame 401 to come into contact with the guide
portion 322a of the second lens frame 320. The positioning portion
412 then moves over the guide portion 322a and reaches the support
portion 322b, and is supported by the support portion 322b. Thus,
the retracting lens frame 401 is thus supported by the second lens
frame 320.
[0456] FIG. 50B shows this state. That is, as shown in FIG. 50B,
when the refracting lens frame 401 is in the refracted position,
the refracting lens frame 401 comes into contact with the support
portion 322b of the second lens group frame 320, and is housed in
the space of the second lens group frame 320, that is, in the space
between the second lens support 321L and the outer peripheral face
320T (see FIG. 45A). More specifically, the refracting lens frame
401 is supported and housed in a state of being in contact with the
support portion 322b of the second lens frame 320 within the space
on the outside in the radial direction of the second lens group
L2.
10. Configuration of Shutter Frame 335
[0457] The configuration of the shutter frame 335 will now be
described through reference to FIGS. 46A, 47A, and 51A to 51C. As
shown in FIG. 46A, the shutter frame 335 has the shutter frame main
body 336, the three rectilinear protrusions A6, and the three cam
protrusions B5. Also, as shown in FIG. 47A, the shutter frame 335
has the opening 356, the light blocking portion 357, and the first
restrictor 337a.
[0458] The shutter frame main body 336 is formed in a cylindrical
shape, and has an outer peripheral face 335T.
[0459] The three rectilinear protrusions A6 are formed on the outer
peripheral face 335T, and are disposed at a substantially constant
pitch in the peripheral direction. The three rectilinear
protrusions A6 are engaged with the three rectilinear grooves a6 of
the third rectilinear frame 130.
[0460] The three cam protrusions B5 are provided to the front end
of the three rectilinear protrusions A6. The three cam protrusions
B5 are engaged with the three cam grooves b5 of the second rotary
frame 220.
[0461] The opening 356 is a portion that houses a part 420b of the
third lens support 420 during the transition period between the
imaging enabled state and the housed state. As shown in FIG. 47A,
the part 420b of the third lens support 420 is the portion adjacent
to the second cut-out 420a during the transition period between the
imaging enabled state and the housed state. More precisely, the
light blocking portion 357 is provided to the opening 356 in order
to block light rays.
[0462] As shown in FIGS. 51A to 51C, the restrictor is a portion
that is configured to restrict movement of the retracting lens
frame 401 in the optical axis direction. The restrictor has a first
restrictor 337a formed near the refraction shaft 501b, and a second
linking portion 408 that acts as a second restrictor and is formed
at a position that is away from the retraction shaft 501b.
[0463] The first restrictor 337a is formed integrally with the
shutter frame main body 336 on the front side (the subject side) of
the first engagement portion 413a. More specifically, the first
restrictor 337a spans the space SK1 (see FIG. 51B) that houses the
members near the refraction shaft 501b, on the front side (the
subject side) of the first engagement portion 413a. The first
restrictor 337a restricts movement of the refracting lens frame 401
in the optical axis direction near the refraction shaft 501b, in
the imaging enabled state and the retracted state.
[0464] The second linking portion 408 is formed integrally with the
OIS frame 400. More specifically, when the refracting lens frame
401 is in the refracted state, the second linking portion 408 spans
to the front side (the subject side) of the space SK2 (see FIG.
47A) that houses the third lens group L3. The second linking
portion 408 restricts movement of the refracting lens frame 401 in
the optical axis direction near the third lens group L3 in the
refracted state.
[0465] During normal operation, that is, when no strong force is
acting on the retracting lens frame 401, such as during an imaging
operation, or when the power is switched on or off, the refracting
lens frame 401 is clamped to the OIS frame 400 by the thrust spring
402, which restricts its position in the optical axis direction.
Therefore, the first restrictor 337a and the second linking portion
408 do not individually come into contact with the first engagement
portion 413a and the second engagement portion 413b. However, if a
strong force (such as when the camera is dropped) is exerted in the
optical axis direction, the refracting lens frame 401 moves in the
optical axis direction with respect to the OIS frame 400 against
the force of the thrust spring 402.
[0466] When a strong force (such as when the camera is dropped) is
exerted in the optical axis direction in the imaging state, the
retracting lens frame 401 moves in the optical axis direction with
respect to the OIS frame 400, and the first restrictor 337a comes
into contact with the first engagement portion 413a. Accordingly,
the thrust spring 402 always is operated in its elastic range.
Here, the engagement of a contact portion 414 with the retraction
shaft 501b contributes to keeping the thrust spring 402 in its
elastic range.
[0467] When a strong force (such as when the camera is dropped) is
exerted in the optical axis direction in the retracted state, the
refracting lens frame 401 moves in the optical axis direction with
respect to the OIS frame 400, and the first restrictor 337a and the
second linking portion 408 come into contact with the first
engagement portion 413a and the second engagement portion 413b.
Consequently, the thrust spring 402 always is operated in its
elastic range.
11. Engagement of Frames
[0468] FIGS. 53 to 55 are cross sections of the lens barrel 20.
However, FIGS. 53 to 55 are schematics that combine a plurality of
cross sections passing through the optical axis AX. The lens barrel
20 is shown in its refracted state in FIG. 53, in its wide angle
state in FIG. 54, and in its telephoto state in FIG. 54. In this
embodiment, the "imaging enabled state" of the digital camera 1
means a state from the wide angle state to the telephoto state of
the lens barrel 20. The gear portion 212 of the first rotary frame
210 meshes with the zoom gear 242 (not shown). The cam followers B1
of the first rotary frame 210 are engaged with the cam grooves b1
of the stationary frame 100. Therefore, the first rotary frame 210
is movable in the optical axis direction while rotating in the
peripheral direction under the drive force of the zoom motor
241.
[0469] The rectilinear protrusions A1 of the first rectilinear
frame 110 are engaged with the rectilinear grooves a1 of the
stationary frame 100. The bayonet protrusions E1 of the first
rotary frame 210 are engaged with the bayonet groove e1 of the
first rectilinear frame 110. Therefore, the first rectilinear frame
110 is movable rectilinearly in the optical axis direction along
with the first rotary frame 210.
[0470] The rectilinear cam followers AB2 of the second rectilinear
frame 120 are inserted into the cam grooves b2 of the first rotary
frame 210, and are engaged with the rectilinear grooves a2 of the
first rectilinear frame 110. Therefore, the second rectilinear
frame 120 is movable rectilinearly in the optical axis direction
according to the rotation of the first rotary frame 210.
[0471] The rectilinear protrusions A3 of the second rotary frame
220 are engaged with the rectilinear grooves a3 of the first rotary
frame 210. The bayonet protrusions E2 of the second rotary frame
220 are engaged with the bayonet groove e2 of the second
rectilinear frame 120. Therefore, the second rotary frame 220 is
movable in the optical axis direction along with the second
rectilinear frame 120 while rotating in the peripheral direction
along with the first rotary frame 210.
[0472] The latching portions 122 of the second rectilinear frame
120 are latched to the latching recesses 133 of the third
rectilinear frame 130. The bayonet protrusions E3 of the third
rectilinear frame 130 are engaged with the bayonet grooves e3 of
the second rotary frame 220. The spacing of at least two of the
three rectilinear protrusions A3 of the second rotary frame 220 is
approximately 120.degree. or more, the spacing of the two latching
portions 122 of the second rectilinear frame 120 is approximately
120.degree. or more, and the relative rotational angle between
these during zoom drive is approximately 120.degree. or less.
Accordingly, the third rectilinear frame 130 is movable
rectilinearly in the optical axis direction along with the second
rectilinear frame 120 without interfering with the rotation of the
second rotary frame 220.
[0473] One of the two latching portions 122 is formed longer in the
peripheral direction than the other one, and correspondingly, one
of the latching recesses 133 is formed longer in the peripheral
direction than the other one, but the third rectilinear frame 130
is preferably made longer in the peripheral direction to the extent
that it does not interfere with the rotation of the second rotary
frame 220.
[0474] The spacing of at least two of the three rectilinear
protrusions A3 of the second rotary frame 220 is approximately
150.degree., the spacing of the two latching portions 122 of the
second rectilinear frame 120 is approximately 150.degree., and the
relative rotational angle between these during zoom drive is
approximately 150.degree. or less. Therefore, the third rectilinear
frame 130 does not interfere with the rotation of the second rotary
frame 220. The same applies to the other angles.
[0475] The rectilinear protrusions A4 of the first lens group frame
310 are engaged with the rectilinear grooves a4 of the second
rectilinear frame 120. Also, the cam protrusions B3 of the first
lens group frame 310 are engaged with the cam grooves b3 of the
second rotary frame 220. Therefore, the first lens group frame 310
is movable rectilinearly in the optical axis direction according to
the rotation of the second rotary frame 220.
[0476] The rectilinear protrusions A5 of the second lens group
frame 320 are engaged with the rectilinear grooves a5 of the third
rectilinear frame 130. Also, the cam protrusions B4 of the second
lens group frame 320 are engaged with the cam grooves b4 of the
second rotary frame 220. Therefore, the second lens group frame 320
is movable rectilinearly in the optical axis direction according to
the rotation of the second rotary frame 220.
[0477] The rectilinear protrusions A6 of the shutter frame 335 are
engaged with the rectilinear grooves a6 of the third rectilinear
frame 130. Also, the cam protrusions B5 of the shutter frame 335
are engaged with the cam grooves b5 of the second rotary frame 220.
Therefore, the shutter frame 335 is movable rectilinearly in the
optical axis direction according to the rotation of the second
rotary frame 220.
[0478] The third lens group frame 330 is mounted to the shutter
frame 335, and when the shutter frame 335 moves rectilinearly in
the optical axis direction with respect to the third rectilinear
frame 130, the retracting lens frame 401 of the third lens group
frame 330 is rotated by a refraction mechanism (the guide groove a7
of the third rectilinear frame 130 and the driven portion 411 of
the refracting lens frame 401). Consequently, in a transition from
the refracted state to the imaging enabled state, the retracting
lens frame 401 moves from its retracted position to a correction
enabled position. Also, in a transition from the imaging enabled
state to the refracted state, the refracting lens frame 401 moves
from the correction enabled position to the refracted position.
When the refracting lens frame 401 is disposed in the correction
enabled position, the third lens group L3 is movable within a plane
perpendicular to the optical axis. That is, image blur correction
is possible in this state.
[0479] Thus, the rotation of the first rotary frame 210 and the
second rotary frame 220 under the drive force of the zoom motor 241
results in rectilinear motion of the lens group frames 310, 320,
and 335 and the first to third rectilinear frames 110 to 130.
Method for Assembling the Lens Barrel 20
[0480] The method for assembling the lens barrel 20 will now be
described.
[0481] First, the third rectilinear frame 130 is inserted from the
rear of the second rotary frame 220. The third rectilinear frame
130 is then rotated in the peripheral direction into the telephoto
state.
[0482] Next, the second lens group frame 320 is inserted from the
rear of the third rectilinear frame 130.
[0483] Next, the refracting lens frame 401 is inserted from the
front of the OIS frame 400, and the refracting lens frame 401 is
rotatably attached to the OIS frame 400.
[0484] Next, the OIS frame 400 is inserted from the front of the
shutter frame 335.
[0485] Next, the shutter frame 335 is inserted from the rear of the
third rectilinear frame 130. The second rotary frame 220 is then
rotated in the peripheral direction into the refracted state.
[0486] Next, the second rotary frame 220 is inserted from the rear
of the first lens group frame 310.
[0487] Next, the second rectilinear frame 120 is installed from the
front of the first lens group frame 310.
[0488] Next, the first rotary frame 210 is inserted from the rear
of the first rectilinear frame 110.
[0489] The second rectilinear frame 120 is then inserted from the
rear of the first rotary frame 210.
[0490] Next, the first rectilinear frame 110 is inserted from the
rear of the stationary frame 100. Finally, the first rotary frame
210 is rotated with respect to the stationary frame 100 into the
refracted state.
Operation and Orientation of Retracting Lens Frame
[0491] The operation and orientation of the refracting lens frame
401 will now be described in detail.
[0492] When the lens barrel 20 transitions from the imaging enabled
state to the refracted state, the refracting lens frame 401 is
moved by a retraction mechanism (the guide groove a7 of the third
rectilinear frame 130 and the driven portion 411 of the retracting
lens frame 401) from the correction enabled position to the
retracted position. Specifically, the retraction mechanism changes
the orientation of the refracting lens frame 401 between an imaging
enabled state and a refracted state. When the lens barrel 20
transitions from the refracted state to the imaging enabled state,
the above operation is performed in reverse to change the
orientation of the refracting lens frame 401 between the imaging
enabled state and the retracted state.
[0493] The refraction mechanism will now be described in detail.
The retracting lens frame 401 moves relatively in the optical axis
direction with respect to the third rectilinear frame 130 from the
imaging enabled state to the refracted state. In the course of this
transition from the imaging enabled state to the refracted state,
the driven portion 411 engages with the guide groove a7 and moves
along the path of the guide groove a7. The guide groove a7 is a cam
mechanism formed in the inner face of the third rectilinear frame
130. The driven portion 411 is a cam follower. As shown in FIG.
42A, a portion (sloped part) that is sloped with respect to the
optical axis and a portion (parallel part) that is parallel to the
optical axis are formed on the guide groove a7. When the driven
portion 411 moves along this sloped part, the retracting lens frame
401 rotates around the refraction shaft 501b. The refracting lens
frame 401 transitions between an image blur correction position and
a refracted position by rotating around the refraction shaft
501b.
[0494] The refracting lens frame 401 integrally engages with the
OIS frame 400 in the optical axis direction, and the OIS frame 400
integrally engages with the shutter frame 335 in the optical axis
direction. Accordingly, the movement of the refracting lens frame
401 with respect to the third rectilinear frame 130 in the optical
axis direction is the same as the movement of the shutter frame 335
with respect to the third rectilinear frame 130 in the optical axis
direction. The rectilinear protrusions A6 of the shutter frame 335
are engaged with the rectilinear grooves a6 of the third
rectilinear frame 130. Also, the cam protrusions B5 of the shutter
frame 335 are engaged with the cam grooves b5 of the second rotary
frame 220. Therefore, the shutter frame 335 is movable
rectilinearly in the optical axis direction according to the
rotation of the second rotary frame 220.
[0495] The OIS frame 400 supported by the shutter frame 335 is
centered by the third rectilinear frame 130 before the retracting
lens frame 401 begins to retract. For example, if there is a
transition from the imaging enabled state to the housed state, when
the shutter frame 335 moves rectilinearly in the optical axis
direction, the shunting protrusions 404 of the OIS frame 400
supported by the shutter frame 335 are mated with the shunting
grooves a9 of the third rectilinear frame 130 from the flange 132
side of the third rectilinear frame 130. When the shutter frame 335
then moves rectilinearly further in the optical axis direction, the
shunting protrusions 404 are pressed by the shunting grooves a9,
and the OIS frame 400 is restricted with respect to the shutter
frame 335. Thus, the centering of the OIS frame 400 is executed
before the retracting lens frame 401 begins its retraction
operation.
[0496] When the refracting lens frame 401 supported by the shutter
frame 335 moves from the image blur correction enabled position to
the retracted position, the refracting lens frame 401 is rotated by
a refraction mechanism consisting of the driven portion 411 of the
refracting lens frame 401 and the guide groove a7 of the third
rectilinear frame main body 131, on the inside of the third
rectilinear frame main body 131. During this time, the refracting
lens frame 401 and the second lens support 321L of the second lens
frame 320 move closer together. The positioning portion 412 of the
refracting lens frame 401 is then guided by the guide portion 322a
of the second lens frame 320 and comes into contact with the
support portion 322b (see FIG. 50A). Consequently, in a state of
having come into contact with the support portion 322b of the
second lens frame 320, the refracting lens frame 401 is housed in
the space of the second lens frame 320, that is, in the space
between the second lens support 321L and the outer peripheral face
320T. More specifically, the refracting lens frame 401 is supported
and housed in a state of being in contact with the support portion
322b of the second lens frame 320 within the space on the outside
in the radial direction of the second lens group L2.
[0497] At this point, the second linking portion 408 of the OIS
frame 400 is housed in the first housing portion 323a of the second
lens frame 320, and the refraction shaft 501b is housed in the
second housing portion 323b of the second lens frame 320 (see FIGS.
45A to 45C).
[0498] Also, at this point, the first linking portion 407 of the
OIS frame 400 is housed in the thinner part 350 of the face of the
shutter frame main body 336 on the front side in the optical axis
direction.
[0499] As shown in FIG. 50B, in this state, the second lens support
321L of the second lens frame 320 is housed in the space ST of the
OIS frame 400 (see FIG. 47A).
[0500] Also, in this state, one end of the thrust spring 402 is
mounted to the OIS frame 400, and the other end of the thrust
spring 402 is mounted to the retracting lens frame 401.
Consequently, the refracting lens frame 401 and the OIS frame 400
are clamped and positioned in the optical axis direction by the
thrust spring 402.
[0501] Also, in this state, the third lens support 420 of the
retracting lens frame 401 is disposed between the first linking
portion 407 and the second linking portion 408. Also, the first
engagement portion 413a (first engagement portion) near the drive
axis of the refracting lens frame 401 is disposed between the first
restrictor 337a and the OIS frame 400. Consequently, as discussed
above, movement of the refracting lens frame 401 in the optical
axis direction is restricted in the event that a powerful force
(such as when the camera is dropped) is exerted in the optical axis
direction.
[0502] Also, in this state, the cut-out 420a formed in the third
lens support 420 of the refracting lens frame 401 is disposed
opposite the light blocking portion 357 of the shutter frame 335.
Also, the opening 356 in the shutter frame 335 houses the part 420b
of the third lens support 420.
[0503] Meanwhile, when the lens barrel is in the imaging enabled
state, the bearing 410 of the refracting lens frame 401 is mated
with the refraction shaft 501b of the OIS frame 400, and the
contact portion 414 of the refracting lens frame 401 comes into
contact with the anti-rotation portion 511 of the OIS frame 400,
which positions the refracting lens frame 401 with respect to the
OIS frame 400 (see FIG. 46A).
[0504] Also, in this state, one end of the thrust spring 402 is
mounted to the OIS frame 400, and the other end of the thrust
spring 402 is mounted to the refracting lens frame 401.
Consequently, the refracting lens frame 401 and the OIS frame 400
are clamped and positioned by the thrust spring 402 in the optical
axis direction.
[0505] Also, in this state, image blur correction on the OIS frame
400 can be accomplished by using the third lens group L3 of the
refracting lens frame 401.
[0506] Also, in this state, the first engagement portion 413a
(first engagement portion) near the drive axis of the retracting
lens frame 401 is disposed between the first restrictor 337a and
the OIS frame 400. Consequently, as discussed above, movement of
the refracting lens frame 401 in the optical axis direction is
restricted in the event that a powerful force (such as when the
camera is dropped) is exerted in the optical axis direction.
Action and Effect
[0507] (1) This lens barrel 20 comprises the shutter frame 335, the
OIS frame 400, and the refracting lens frame 401. The OIS frame 400
is supported by the shutter frame 335, and is movable within a
plane that is perpendicular to the optical axis with respect to the
shutter frame 335. The retracting lens frame 401 is supported by
the OIS frame 400, and moves around the refraction shaft 501b,
which is substantially parallel to the optical axis, during the
transition period between the imaging enabled state and the housed
state. The shutter frame 335 has the shutter frame main body 336
and the first restrictor 337a (an example of a first restrictor).
The first restrictor 337a is provided a specific distance away from
the shutter frame main body 336. The refracting lens frame 401 has
the first engagement portion 413a that engages with the first
restrictor 337a. Because the first engagement portion 413a is
disposed between the shutter frame main body 336 and the first
restrictor 337a, movement of the refracting lens frame 401 in the
optical axis direction is restricted.
[0508] Thus, with this lens barrel 20, movement of the refracting
lens frame 401 in the optical axis direction is restricted by the
first restrictor 337a in the imaging enabled state. Accordingly,
even if the lens barrel is subjected to an impact force, such as
when the camera is dropped, movement of the retracting lens frame
401 in the optical axis direction is restricted. Specifically, the
refracting lens frame 401 is reliably supported with respect to the
OIS frame 400. That is, the refracting lens frame 401 is operated
stably.
[0509] (2) With this lens barrel 20, the first restrictor 337a is
formed near the refraction shaft 501b. The OIS frame 400 has the
second linking portion 408, which is formed away from the
refraction shaft 501b. The refracting lens frame 401 further has a
second engagement portion 337b that engages with the second linking
portion 408 during the transition period between the imaging
enabled state and the housed state.
[0510] Thus, with this lens barrel 20, movement of the refracting
lens frame 401 in the optical axis direction is restricted by the
first restrictor 337a in the imaging enabled state. Also, in the
housed state, movement of the refracting lens frame 401 in the
optical axis direction is restricted by the first restrictor 337a
and the second linking portion 408. Accordingly, even if the lens
barrel is subjected to an impact force, such as when the camera is
dropped, movement of the refracting lens frame 401 in the optical
axis direction is reliably restricted by the above-mentioned
configuration. Specifically, the retracting lens frame 401 is more
reliably supported with respect to the OIS frame 400. That is, the
retracting lens frame 401 is operated more stably.
Other Embodiments
[0511] (A) In the above embodiment, the lens barrel 20 had a
three-stage telescoping design made up of the first rectilinear
frame 110, the second rectilinear frame 120, and the first lens
group frame 310, but this is not the only option. The lens barrel
20 may instead have a two-stage telescoping design made up of the
first rectilinear frame 110 and the second rectilinear frame 120.
In this case, the lens barrel 20 need not comprise the second
rotary frame 220 or the third rectilinear frame 130. The lens
barrel 20 may also have a four-stage or higher telescoping
design.
[0512] (B) In the above embodiment, the cam grooves b were formed
on one of two frames, and the cam protrusions B were formed on the
other frame, but this is not the only option. The frames on which
the cam protrusions B and the cam grooves b are formed may be
switched around. Also, the cam grooves b and the cam protrusions B
may both be formed in each of the two frames.
[0513] (C) In the above embodiment, the rectilinear grooves a were
formed in one of two frames, and the rectilinear protrusions A were
formed in the other frame, but this is not the only option. The
frames on which the rectilinear protrusions A and the rectilinear
grooves a are formed may be switched around. Also, the rectilinear
grooves a and the rectilinear protrusions A may both be formed in
each of the two frames.
[0514] (D) In the above embodiment, the bayonet grooves e were
formed in one of two frames, and the bayonet protrusions E were
formed in the other frame, but this is not the only option. The
frames on which the bayonet protrusions E and the bayonet grooves e
are formed may be switched around. Also, the bayonet grooves e and
the bayonet protrusions E may both be formed in each of the two
frames.
[0515] (E) In the above embodiment, the third lens group frame 330
was retracted toward the second lens group frame 320 in the
retracted state, but this is not the only option. The third lens
group frame 330 may be disposed to the rear of the second lens
group frame 320 in the retracted state.
[0516] (F) In the above embodiment, as shown by the broken line in
FIG. 56A, the other end 403b of the rotary spring 403 is formed so
as to extend away from the axis KJ of the coil part at a position
of 90 degrees with reference to the axis KJ of the coil part of the
rotary spring 403 (the axis of the coil part, the axis of the
refraction shaft 501b). Instead, as shown by the solid line in FIG.
56A, the other end 403b' of the rotary spring 403 may be formed so
as to extend away from the axis KJ of the coil part at a position
of greater than 90 degrees with reference to the axis KJ of the
coil part.
[0517] In this case, just as in the above embodiment, if the rotary
spring 403 is mounted to the OIS frame 400 and the refracting lens
frame 401, the force FP at which the refracting lens frame 401 is
pressed against the OIS frame 400 is generated, as shown in FIG.
56B. This allows the three first contact portions 603A (603A1,
603A2, and 603A3) of the retracting lens frame 401 to be reliably
brought into contact by the OIS frame 400.
[0518] (G) In the above embodiment, an example was given in which,
when the second rotary frame 220 (third frame body) rotated, the
shutter frame 335 and the OIS frame 400 (second frame body) moved
in the optical axis direction with respect to the third rectilinear
frame 130 (first frame body) via the third rectilinear frame 130
(first frame body).
[0519] Instead, the first and second frame bodies may be configured
to be capable of relative rotation, and the second and third frame
bodies may be configured to be incapable of relative rotation. In
this case, the through-groove of the first frame body extends in
the optical axis direction and the peripheral direction.
[0520] With this configuration, when the first frame body rotates,
the second frame body (such as the shutter frame 335 and/or the OIS
frame 400) and the refracting lens frame moves in the direction of
the guide grove of the third frame body, such as the optical axis
direction. Also, at this point the retracting lens frame 401 moves
in a direction perpendicular to the optical axis, with respect to
the second frame body.
[0521] Thus, even when the lens barrel 20 is configured so that the
second frame body, such as the shutter frame 335 and/or the OIS
frame 400, moves in the optical axis direction with respect to the
third frame body, the driven portion 411 and the guide groove a7
are provided, and the retracting lens frame 401 is operated, just
as in the above embodiment. This gives the same effect as
above.
[0522] (H) In the above embodiment, an example was given in which
the anti-rotation portion 511 of the OIS frame 400 was formed in a
concave shape, and the upper face of the second contact portion
603B of the retracting lens frame 401 came into contact with the
recess 512. Instead, as shown in FIG. 57, the second contact
portion 603B of the retracting lens frame 401 may come into contact
with two side faces 512a' of a recess 512' of an anti-rotation
portion 511'. In this case, the two side faces 512a' of the recess
512' are inclined and opposite each other. More specifically, the
two side faces 512a' of the recess 512' are formed so as to move
closer together toward the bottom 512b' of the recess 512'.
Consequently, the retracting lens frame 401 is be more reliably
positioned with respect to the OIS frame 400.
General Interpretation of Terms
[0523] In understanding the scope of the present disclosure, the
term "comprising" and its derivatives, as used herein, are intended
to be open ended terms that specify the presence of the stated
features, elements, components, groups, integers, and/or steps, but
do not exclude the presence of other unstated features, elements,
components, groups, integers and/or steps. The foregoing also
applies to words having similar meanings such as the terms,
"including", "having" and their derivatives. Also, the terms
"part," "section," "portion," "member" or "element" when used in
the singular can have the dual meaning of a single part or a
plurality of parts. Also as used herein to describe the above
embodiment(s), the following directional terms "forward",
"rearward", "above", "downward", "vertical", "horizontal", "below"
and "transverse" as well as any other similar directional terms
refer to those directions of the lens barrel. Accordingly, these
terms, as utilized to describe the present technology should be
interpreted relative to the lens barrel.
[0524] The term "configured" as used herein to describe a
component, section, or part of a device implies the existence of
other unclaimed or unmentioned components, sections, members or
parts of the device to carry out a desired function. The terms of
degree such as "substantially", "about" and "approximately" as used
herein mean a reasonable amount of deviation of the modified term
such that the end result is not significantly changed.
[0525] While only selected embodiments have been chosen to
illustrate the present technology, it will be apparent to those
skilled in the art from this disclosure that various changes and
modifications can be made herein without departing from the scope
of the technology as defined in the appended claims. For example,
the size, shape, location or orientation of the various components
can be changed as needed and/or desired. Components that are shown
directly connected or contacting each other can have intermediate
structures disposed between them. The functions of one element can
be performed by two, and vice versa. The structures and functions
of one embodiment can be adopted in another embodiment. It is not
necessary for all advantages to be present in a particular
embodiment at the same time. Every feature which is unique from the
prior art, alone or in combination with other features, also should
be considered a separate description of further technologies by the
applicant, including the structural and/or functional concepts
embodied by such feature(s). Thus, the foregoing descriptions of
the embodiments according to the present technologies are provided
for illustration only, and not for the purpose of limiting the
technology as defined by the appended claims and their
equivalents.
INDUSTRIAL APPLICABILITY
[0526] The technology disclosed herein can be widely applied to
lens barrels.
* * * * *